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Synthesis and Characterization of New Ferrocenyl-Containing Tin(IV) and Indium(III) Porphyrins
A THESIS
SUBMITTED TO THE FACULTY OF THE GRADUATE SCHOOL OF THE UNIVERSITY OF MINNESOTA
BY
Samantha Jolene Dammer
IN PARTIAL FULFILLMENT OF THE REQUIREMENTS FOR THE DEGREE OF MASTER OF SCIENCE
Advised by Dr. Victor Nemykin
July 2011
© Samantha Jolene Dammer 2011
i
Acknowledgements
I would first like to express great gratitude to my advisor Dr. Victor Nemykin for
his support and encouragement throughout my research. I would like to show my
appreciation to Pavlo Solntsev for his patience and guidance in the lab. I would also like
to thank Jared Sabin, for his aid in teaching me how to use all the instrumentation and for
running all of the computational chemistry. Lastly, I would like to thank the UMD
Chemistry Department as a whole for its support and the National Science Foundation
for funding (Grants CHE-0809203 and CHE-0922366) and the Minnesota Super
Computing Institute.
Part one is reprinted with permission from Chemical Communications. 2010, 46, 658. Copyright 2010. The Royal Society of Chemistry; http://pubs.rsc.org/en/content/articlelanding/2010/cc /c0cc02171g
ii
For Andy, Mom, Dad, and Sarah
&
To Those Trying to Set the World on Its Ear
iii
Abstract
A series of new tin (IV) σ-bonded ferrocene-containing porphyrins, FcXSnTPP
complexes (X = Fc or Cl; TPP = 5,10,15,20-tetraphenylporphyrin(2-)) and FcXSnOEP
complexes (X = Fc or OEt; OEP = 5,10,15,20-octaethylporphyrin(2-)), have been
prepared and characterized using 1H NMR, UV-Vis, and MCD spectroscopy. Structures
of all target compounds were confirmed by single crystal X-ray analysis. The redox
properties of these compounds were investigated using electrochemistry,
spectroelectrochemistry, and chemical oxidation techniques. It has been found that the
presence of one or more ferrocene groups leads to controlled redox behaviors that can
have potential application in optical and fluorescent sensors. Three new indium(III) poly-
ferrocenyl porphyrins (XInTFcP complexes [X = Cl, OH, or Fc; TFcP = 5,10,15,20-
tetraferrocenylporphyrin(2-)] have also been prepared and investigated by the similar
methods. Through redox property analysis, mixed-valence state formations were
observed between Fe(II)-Fe(III) centers. The mixed-valence nature of these compounds
makes them candidates for molecular electronics. DFT calculations were also performed
in order to understand the electronic structure and its relation to the redox properties
involved for some of the compounds.
iv
Table of Contents Acknowledgements i
Abstract ii
Table of Contents iv
Table of Figures vi
Table of Tables ix
Table of Schemes x
Introduction 1
1. σ- Bonded Ferrocene Containing Tin (IV) Pophryins 2
Introduction 2
Synthesis 4
X-Ray Analysis 5
NMR Spectroscopy 12
UV-Vis and MCD 15
Electrochemistry 16
Spectroelectrochemistry 18
Chemical Oxidation Titrations 20
Fluorescence Oxidation Titrations and Quantum Yield 24
Electronic Structure 28
Conclusions 33
2. Indium (III) Poly-Ferrocenyl Containing Porphyrins 34
Introduction 34
v
Synthesis 35
X-Ray Analysis 37
NMR Spectroscopy 42
UV-Vis and MCD 50
Electrochemistry 52
Spectroelectrochemistry 55
Chemical Oxidation Titrations 59
Electronic Structure 64
Conclusions 66
Experimental Section 67
Materials 67
Synthesis 67
Instrumentation 73
Computation Aspects 73
X-Ray Crystallography 74
References 78
Supplemental Information 82
1. Inter-Valence Charge Transfer Band Analysis 82
2. Electrochemical Data Deconvolution Analysis 83
3. CIF Information for 2, 3, 4, 5, 6, and 8 84
vi
Table of Figures
Figure 1: Robin-Day Classification for Mixed-Valence State Compounds 1
Figure 2: Crystal Structure of FcClSnTPP (2) 5
Figure 3: Crystal Structure of Fc2SnTPP (3) 6
Figure 4: Crystal Structure of Fc(OCH2CH3) (4) 6
Figure 5: Crystal Structure of Fc2SnOEP (5) 7
Figure 6: Role of C-H···π Packing Interactions of Compound 2 9
Figure 7: 1H NMR Spectrum of Cl2SnTPP (1) 12
Figure 8: 1H NMR Spectrum of FcClSnTPP (2) 13
Figure 9: 1H NMR Spectrum of Fc2SnTPP (3) 14
Figure 10: UV Vis (top) and MCD (bottom) Spectra of Compounds Cl2SnTPP (1), 16
FcClSnTPP (2), and Fc2SnTPP (3)
Figure 11: Spectroelectrochemical Titration Plot for FcClSnTPP (2) 19
Figure 12: Spectroelectrochemical Titration Plot for Fc2SnTPP (3) 20
Figure 13: Chemical Oxidation Titration using AgOTf Plot of FcClSnTPP (2) 21
Figure 14: Chemical Oxidation Titration using DDQ Plot of FcClSnTPP (2) 22
Figure 15: Chemical Oxidation Titration using AgOTf Plot of Fc2SnTPP (3) 23
Figure 16: Stand-still Comparitive Emission Spectra of 1, 2, and 3 25
Figure 17: Quantum Yield Comparison of 1, 2, and 3 25
Figure 18: Fluorescence Oxidation Titration using p-chloranil Plot of FcClSnTPP (2) 27
Figure 19: Fluorescence Oxidation Titration using p-chloranil Plot of Fc2SnTPP (3) 27
Figure 20: Molecular Orbital Energy Diagram of 1, 2, and 3 28 Figure 21: Molecular Orbital Contribution Diagram of Cl2SnTPP (1) 29 Figure 22: Molecular Orbital Contribution Diagram of FcClSnTPP (2) 30
vii
Figure 23: Molecular Orbital Contribution Diagram of Fc2SnTPP (3) 30
Figure 24: Selected Molecular Orbital Images for 1, 2, and 3 30, 31, 32
Figure 25: Time Dependent Density Functional Theory Plots of 1, 2, and 3 33
Figure 26: Crystal Structure of ClInTFcP (6) 37
Figure 27: Crystal Structure of FcInTFcP (8) 38
Figure 28: Zig-zag Packing of Complex 6 40
Figure 29: π-π Stacking of Complex 8 41
Figure 30: 1H NMR of ClInTFcP (6) 43
Figure 31: 1H NMR of OHInTFcP (7) 43
Figure 32: 1H NMR of FcInTFcP (8) 44
Figure 33: GCOSY of FcInTFcP (8) 45
Figure 34: Variable Temperature Data for FcInTFcP (8) 46
Figure 35: Variable Temperature Data for ClInTFcP (6) 46
Figure 36: 13C NMR of ClInTFcP (6) 48
Figure 37: 13C NMR of OHInTFcP (7) 48
Figure 38: 13C NMR of FcInTFcP (8) 49
Figure 39: HMQC of FcInTFcP (8) 49
Figure 40: UV-Vis and MCD of Compound 6 50
Figure 41: UV-Vis and MCD of Compound 7 51
Figure 42: UV-Vis and MCD of Compound 8 51
Figure 43: Electrochemical Plots for 6, 7, and 8 52
Figure 44: Spectroelectrochemical Titration Plot for Complex 6 56
Figure 45: Spectroelectrochemical Titration Plot for Complex 7 57
Figure 46: Spectroelectrochemical Titration Plot for Complex 8 58
Figure 47: Chemical Oxidation Titration using AgOTf Plot of Compound 6 60
viii
Figure 48: Chemical Oxidation Titration using DDQ Plot of Compound 6 60
Figure 49: Chemical Oxidation Titration using DDQ Plot of Compound 7 61
Figure 50: Chemical Oxidation Titration using AgOTf Plot of Compound 8 62
Figure 51: Molecular Energy Orbital Diagram of Compounds 6 and 8 64
Figure 52: Molecular Orbital Contribution Diagram of Compound 6 65
Figure 53: Molecular Orbital Contribution Diagram of Compound 8 65
Figure 54: Disorder of Ferrocene by Rotation around Sn-C Bond in 2 76
Figure 55: Disorder of Cp-ring by Rotation around Fe atom in 4 77
Figure 56: Disorder of ClInTFcP (6) Moiety and Toluene Molecule 77
ix
Table of Tables
Table 1. Table of Selected Bond Lengths (Å ) and Angles (°) for Compound 2 8
Table 2: Table of Selected Bond Lengths (Å ) and Angles (°) for Compound 3 8
Table 3: Table of Selected Bond Lengths (Å ) and Angles (°) for Compound 4 8
Table 4: Table of Selected Bond Lengths (Å ) and Angles (°) for Compound 5 8
Table 5: Table of Selected Crystallographic Parameters of Compounds 2 and 3 10
Table 6: Table of Selected Crystallographic Parameters of Compounds 4 and 5 11
Table 7: Summary of Electrochemical DPV Data for FcClSnTPP (2) 17
Table 8: Summary of Electrochemical DPV Data for Fc2SnTPP (3) 18
Table 9: Table of Selected Bond Lengths (Å ) and Angles (°) for Compound 6 39
Table 10: Table of Selected Bond Lengths (Å ) and Angles (°) for Compound 8 39
Table 11: Table of Selected Crystallographic Parameters of Compounds 6 and 8 41
Table 12: Summary of Electrochemical DPV Data for Compound 6 53
Table 13: Summary of Electrochemical DPV Data for Compound 7 54
Table 14: Summary of Electrochemical DPV Data for Compound 8 55
Table 15: Estimation Estimated magnitudes of Hab and α for mixed-valence
[ClInTFcP]+, [OHInTFcP]+, and [FcInTFcP]2+ complexes 63
x
Table of Schemes
Scheme 1: Preparation of FcxClySn TPPs and OEPs (2, 3, 4, and 5) 4
Scheme 2: Oxidation of Ferrocene Unit to Show Emission Scheme 26
Scheme 3: Preparation of ClInTFcP (6) 36
Scheme 4: Preparation of HOInTFcP (7) 36
Scheme 5: Preparation of FcInTFcP (8) 37
1
Introduction:
Mixed-valence compounds represent an important class of organometallic
complexes. Electron transfer between two metallocenters, induced either optically or
thermally, is responsible for mixed-valency1,2,3,4. According to Robin and Day
classification4, mixed-valence compounds can be
categorized into three classes. In a Class I mixed-valence
system, the metal ions do not communicate with each other
because of the ligand field strength difference, which
makes electron transfer between the two centers
impossible. A Class II mixed-valence compound can
undergo electron transfer either optically or thermally. As
electron transfer occurs, the oxidation states of the metal
ions, located in the same environment, change. Electron
transfer is a relatively slow, which allows separate
characterizations of oxidation and reduction between
metallocenters to be examined. For instance, when
dinuclear iron complexes are considered, electron transfer
to an Fe(II)/ Fe(III) center is slow, and two of these centers exhibit different spectroscopic
signatures in the UV-Vis-NIR region4. These signatures can be characterized by the
presence of solvent independent inter-valence charge transfer (IVCT) bands4. These
bands display different energies (υmax), intensities (ε) and bandwidths at half height
(∆υ1/2),4which can be used for the estimation of the coupling matrix element. Class III
mixed-valence electron transfer between two metallocenters is faster and thus such
Figure 1: Robin and Day Classification for MixedValence State Compounds
2
compounds can be characterized as a valence average system. All types of behavior can
be seen in Figure 1.
In the majority of cases, the mixed-valence properties in dinuclear metallated
systems when metal distances are less than 5 or 6 Å are known, while examples of these
systems with a long range (10-12 Å) metal-metal coupling are rare5. These examples
include different types of porphyrins5,6,7, tetraazaporphyrins8, pthalocyanines9, corroles10
and their nonaromatic analogues10. The outstanding chemical and thermal stability, as
well as the possibility of fine-tuning their redox potentials, make these compounds
outstanding candidates for many areas of research. Not only can these compounds be
used to mimic different biological transfer systems12, but they can be potentially useful as
nanoscale materials13. For instance, these compounds can be incorporated into molecular
based electronic devices such as molecular multibit information storage elements and
also molecular electrogenic sensors14.
The following two chapters report the redox abilities of new poly(ferrocenyl)
tin(IV) and indium(III) containing porphyrins. Each has been characterized using NMR,
MCD, and crystal structure analysis. Electrochemical, spectroelectrochemical, and UV-
Vis-NIR techniques were also performed to test their applicability for chemical sensing
or molecular electronics.
Part 1 - σ-Bonded Ferrocene Containing Tin (IV) Porphyrins:
Introduction:
For creating a mixed valence system, ferrocene is an attractive ligand. As a matter
of fact, directly- linked ferrocenyl compounds were among the first mixed-valence
3
organometallic materials. Poly-ferrocenyl substituted complexes can exhibit multiple
redox processes and are very well known for their metal to metal coupling and excellent
thermal stability.15 Reports of porphyrins and their analogues with axial ferrocene
substituents directly σ-bonded to the central metal are extremely rare and are limited to
the Fc2GeP and FcPhGeP (P = TPP2- or OEP2-) complexes reported by Kadish and co-
workers at the end of the 1980s.16 It should be mentioned that these compounds were not
prepared in high purity.16 Not surprisingly, molecular structures of these complexes have
never been determined by X-ray crystallography. It has been mentioned that unlike the
other porphyrins with alkyl- and aryl-substituents σ-bonded to the central metal, axial
Fc2MP complexes are stable in solution and do not easily undergo M–Fc bond cleavage
under photochemical conditions because of the effective quenching of excited states by
ferrocene substituents.15a Such a quenching mechanism is commonly believed to be
responsible for the extremely low fluorescence quantum yields in ferrocenyl-containing
porphyrins with direct ferrocene–macrocyclic bonding. Indeed, as was shown recently,17
oxidation of the ferrocene substituent in zinc 5-ferrocenyl-10,15,20- tri(aryl)porphyrins
leads to the dramatic increase of the fluorescence quantum yields and thus opens a
potential application of such molecules in fluorescent imaging. Similar redox-driven
fluorescence response for porphyrins with axial ferrocene substituents directly σ-bonded
to the central metal has never been studied.
The formation and characterization of new Sn(IV) compounds have been
examined and reported in this chapter. Each new product has been evaluated for its
molecular structure, redox, and fluorescence properties, and has been compared to the
parent porphyrin and other ferrocenyl-containing porphyrins. It has been found that with
4
single or multiple redox-active ferrocene groups, these compounds have controlled redox
behaviors that can have potential application in optical and fluorescent sensory devices.
Synthesis:
Two new Sn(IV) tetraphenyl porphyrins (TPPs) have been created by low-
temperature interactions with a ferrocene lithium (FcLi) salt and SnCl2TPP18 (1). From
this reaction (Scheme 1), the axial chloride substituents are substituted by ferrocene
groups. Varying the amounts of FcLi salt used in the reaction will give mono- or di-
chloro substitution. For example, a 5 mmol excess of FcLi salt may show replacement of
only one chloride group (2), where a 6 mmol excess displays replacement of both
chlorines in the starting precursor (3). Both of the new compounds are stable, not only in
solid state, but also in acid-free solutions. Two new Sn(IV)octaethyl porphyrins (OEPs),
4 and 5, have been prepared the same way as 2 and 3, but are not quite as stable in
solution. Because of this instability, the axial chloro-substituent in 4 was found to have
been replaced by an ethoxy group via column chromatography.
Scheme 1: Preparation of FcxClySn TPPs and OEPs (2,3,4, and 5)
X
N N
NN
Ph
Ph
Ph
PhSn
Fe
Cl
N N
NN
Ph
Ph
Ph
PhSn
ClFcLi
ether/toluener.t. 30 min
X = Cl (2), Fc (3)
Cl
N N
NNSn
ClFcLi
ether/toluener.t. 30 min
X
N N
NNSn
Fe
X= OCH2CH3 (4) , Fc (5)
5
X-Ray Crystal Structures:
Tin(IV) containing porphyrins usually form symmetrically substituted
compounds, and they usually contain σ-donor ligands like alcohols or acids. However,
some other examples of tin(IV) porphyrins are also known. Arnold and co-workers
reported crystal structures for the trans- and cis- isomers of Ph2SnTPP19, while Woo and
co-workers reported a crystal structure of Sn(IV) porphyrin with phenylacetylene
ligand.20 Four new metal-organic compounds (2, 3, 4, and 5 (Scheme 1)) were
characterized by single crystal x-ray analysis. All compounds were crystallized in
triclinic symmetry with P-1 space group. The tin metal 4+ cation in porphyrins usually
adopts six-coordinate octahedral geometry, which consists of four nitrogens and two
extra atoms for axially coordinated substituents. The new porphyrin systems reported
here are unique because the axial ferrocene substitution reactions examined here yielded
both unsymmetrical (2 and 4) and symmetrical (3 and 5) compounds.
Figure 2: Crystal Structure of FcClSnTPP (2)
6
Figure 3: Crystal Structure of Fc2SnTPP (3)
Figure 4: Crystal Structure of Fc(OCH2CH3)SnOEP (4)
7
Figure 5: Crystal Structure of Fc2SnOEP (5)
Crystal structures of 2, 3, 4, and 5 are shown in Figures 2, 3, 4, and 5,
respectively. In complexes, 3 and 5, tin lies in the plane of the porphyrin, while with 2
and 4 the central tin metal sits above the porphyrin system (Sn-{C16,C11, C6, C1
(plane)} = 0.296Å (2) and Sn {C16,C11,C6,C1(plane)}= 0.216Å (4)). The coordination
environment of tin(IV) for these unsymmetrical systems consists of the four nitrogen
atoms of the porphyrin core (Sn-N=2.104(4)-2.120(4) Å for 2 and 2.117(2)-2.121(2) Å
for 4), one carbon atom of the ferrocenyl ligand (Sn-C =2.159(5) Å (2), 2.130(4) Å (4),
and either a chloride (Sn-Cl=2.498(9) Å) or an ethoxo (Sn-O=2.175(4) Å) ligand for 2
and 4, respectively. For symmetric compounds 3 and 5, two fold symmetry independent
of Sn-N can be seen and is the same and equal to two times 2.094(7) and 2.131(2),
2.132(2), correspondingly. It is of interest to note, that Sn-C distances for both
8
compounds are shorter than that for trans-Ph2SnTPP (2.196(4) Å and 2.212(4) Å)21, even
though ferrocene molecules are bulkier compared to phenyl groups. This fact also brings
about an idea related to the stability of the Sn-C bond for ferrocenyl substituted tin(IV)
porphyrin versus phenyl analog systems. A comparable Sn-C bond was also observed for
asymmetric Sn(C≡C-Ph)(OC6H4OH)TPP (2.140(1)) Å22.
Table 1: Table of Selected Bond Lengths (Å ) and Angles (°) for Compound 2
Selected Bond Lengths (Å) and Angles (°) for 2 Sn(1)-N(4) 2.117(2) Sn(1)-N(1) 2.121(2) N-Sn(1)-C(45) 93.44(13)-97.14(13) Sn(1)-N(2) 2.119(2) Sn(1)C(45) 2.130(4) N-Sn(1)-Cl(1) 84.58(8)-84.81(7) Sn(1)-N(3) 2.119(2) Sn(1)-Cl(1) 2.4981(9) C(45)-Sn(1)-Cl(1) 177.25 (11)
Table 2: Table of Selected Bond Lengths (Å ) and Angles (°) for Compound 3
Selected Bond Lengths (Å) and Angles (°) for 3 Sn(1)-N(1) 2.132(2) C(23)-Sn(1)-N(2) 87.78(10)
Sn(1)-N(2) 2.131(2) C(23)-Sn(1)-N(1) 94.10(9)
Sn(1)-C(23) 2.186(3) C(23)-Sn(1)-C(23)#1 179.995
Table 3: Table of Selected Bond Lengths (Å ) and Angles (°) for Compound 4
Table 4: Table of Selected Bond Lengths (Å ) and Angles (°) for Compound 5
Selected Bond Lengths (Å) and Angles (°) for 4 Sn(1)-N(4) 2.120(4) Sn(1)-N(1) 2.108(4) N-Sn(1)-O(1) 82.56(16)-88.12(15) Sn(1)- N(2) 2.109(4) Sn(1)-C(37) 2.159(5) N-Sn(1)-C(37) 90,85(17)-100.56(17) Sn(1)-N(3) 2.104(4) Sn(1)-O(1) 2.175(4) C(37)-Sn(1)-O(1) 174.74(15)
Selected Bond Lengths (Å) and Angles (°) for 5 Sn(1)-N 2.094(7) N(9)-Sn(1)-C(3) 88.7(3)
Sn(1)-C(3)#1 2.170(10) N(2)-Sn(1)-C(3) 85.8(3)
Sn(1)-C(3) 2.170(10) C(3)-Sn(1)-C(3)#1 180 (1)
9
The crystal packing diagram of 2 is shown above in Figure 6. It can be found that
p-phenyl ring protons interact with aromatic π-cloud systems of neighboring phenyl rings
by C-H···π interactions. The average distance between the C···Centroid is 3.660 Å, while
the distance for H···centroid is 2.760 Å, and the angle C-H-centroid is 158.40°.
Compound 3 packs with similar fashion but distances between protons and π-systems are
much longer—3.892. This type of interaction can also be observed for other similar
compounds, for example SnCl2TPP has average C···Centroid distances of 4.4095 Å, with
H···centroid distances of 4.095 Å.23
Figure 6: Role of C-H···π Packing Interactions of Compound 2
10
Table 5: Selected Crystallographic Parameters of Compounds 2 and 3
Selected Crystallographic Parameters of 2 and 3 2 3 Empirical formula C56.98 H43.96 Cl Fe N4 Sn C64H46Fe2N4Sn Formula weight 994.67 1101.48 Crystal system Triclinic Triclinic Space group, Z P-1, 2 P-1, 1 a (Å) 13.2771(2) 10.737(1) b (Å) 13.3199(2) 11.288(1) c (Å) 15.2657(10) 12.173(1) α (°) 114.559(8) 101.657(1) β (°) 95.207(7) 108.082(1) γ (°) 90.164(6) 115.058(1) Volume (Å3) 2442.91(17) 1171.4(2) ρcalc(g/cm3) 1.352 1.561 μ(Mo-Kα)(mm-1) 0.904 1.189 θmax(°) 27.6 29.13 Reflections collected/unique, Rint 82535 / 11207, 0.0635 16707 / 6273, 0.034 Data/restraints/parameters 11207 / 71 / 659 6252 / 0 / 322 GooF(F2) 1.036 0.9889 R1a, wR2b(F2>2σ(F2)) 0.0451, 0.1128
0.0354, 0.0901
R1a, wR2b (all data) 0.0560, 0.1179 0.0485, 0.1059 Δρmax/Δρmin (e/Å3) 1.356 / -0.723 1.41 / -1.46
R1(F) =Σ||Fo| - |Fc||/Σ|Fo|. bwR2(F2) = {Σ[w(Fo2 – Fc2)2]/Σw(Fo2)2]}1/2. w1/2 = [1.0/(2.14*t[0]'(x)+2.62*t[1]'(x)+0.644*t[2]'(x))]1/2,x = Fo/Fomax
11
Table 6: Table of Selected Crystallographic Parameters of Compounds 4 and 5
Selected Crystallographic Parameters of 4 and 5 4 5 Empirical formula C48H54FeN4OSn C56H62Fe2N4Sn Formula weight 877.49 1021.49 Crystal system Triclinic Triclinic Space group, Z P-1, 2 P-1, 1 a (Å) 10.047(5) 9.585(3) b (Å) 14.695(5) 10.313(3) c (Å) 15.322(5) 13.370(4) α (°) 73.676(5) 68.393(6) β (°) 80.334(5) 85.796(6) γ (°) 80.399(5) 66.759(5) Volume (Å3) 2123.0(15) 1157.1(6) ρcalc(g/cm3) 1.373 1.466 μ(Mo-Kα)(mm-1) 0.970 1.197 θmax(°) 20.79 27.48 Reflections collected/unique, Rint 26925 / 4395, 0.0271 27643/5107, 0.1441 Data/restraints/parameters 4395 / 80 / 551 5107 / 0 / 286 GooF(F2) 1.056 1.026 R1a, wR2b(F2>2σ(F2)) 0.0401, 0.1098 0.0963, 0.2459 R1a, wR2b (all data) 0.0440, 0.1125 0.1529, 0.2831 Δρmax/Δρmin (e/Å3) .982/ -0.652 1.638 / -1.550 aR1(F) =Σ||Fo| - |Fc||/Σ|Fo|. bwR2(F2) = {Σ[w(Fo2 – Fc2)2]/Σw(Fo2)2]}1/2.
w1/2 = [1.0/(2.14*t[0]'(x)+2.62*t[1]'(x)+0.644*t[2]'(x))]1/2,x = Fo/Fomax
12
NMR Spectra:
The parent SnCl2TPP (1) exhibits 3 different signals in proton NMR. The
porphyrin ring itself contributes one of these signals for the β-pyrrolic protons. These
protons lie furthest downfield at 9.23 ppm. Two signals that also appear on the spectrum
originate from the phenyl ring. The two protons directly nearby the coordination site, the
o-Ph’s, are located in a multiplet at 8.34 ppm. The meta and para protons, m-Ph and p-Ph,
are found as one entity within a doublet at 7.85 ppm24.
Figure 7: 1H NMR Spectrum of Cl2SnTPP (1)
Many of the same signals found for the parent precursor Cl2SnTPP (1) can be
seen in the spectrum for compound 2 with the addition of three more signals—all from
the new ferrocene substituent. Ferrocene is a sandwich compound in which an iron(II)
metal ion is located between two cyclopentadienyl ligands. When looking at the bond
between just one of those cyclopentadienyl rings and the porphyrin core, the two protons
closest to the connecting carbon are typically labeled alpha (α). The other two protons on
that ring are designated beta (β). The protons belonging to the unsubstituted
13
cyclopentadienyl ring maintain equivalency with each other and appear as one signal.
These are labeled “Cp-H”. All ferrocenyl protons are located near each other in and a
2:2:5 proton ratio. Axially substituted ferrocenes are found to be shifted upfield. The
alpha proton is found furthest upfield at -1.17 pm due to π-system ring current running
through the macrocycle which affects its closest axially bonded substituents (the α-Cp
protons). Similar spectral features were observed by Kadish with his axially
diferrocenally substituted germanium porphryins19.
Continuing downfield lie the Cp-H protons at 2.08 ppm and the β-Cps at 2.35
ppm. Next in the aromatic region of the spectrum, the meta and para protons are found at
7.83 ppm. The three protons are not seen as one multiplet, but rather a triplet and quartet
overlapped. These protons are depicted Hc, Hd, and He below. The two ortho protons are
also observed differently. Two doublets are located at 8.25 ppm and 8.38 ppm for the Hb
and Ha protons, respectively. A β-pyrrolic proton signal is also found furthest downfield
at 9.12 ppm.
Figure 8: 1H NMR Spectrum of FcClSnTPP (2)
14
The signals found for compound 3 are similar to those found for 1 and 2, now
with the difference being that it contains two axial ferrocene substituents. There is a β-
pyrrolic signal again furthest downfield at 8.96 ppm, followed by two phenyl ring signals.
The ortho protons appear together as one peak and so do the meta- and para- protons
combined—lying at 8.30 ppm and 7.80 ppm respectively. The two ferrocenyl substituents
exhibit their signals together, giving a β-Cp signal at 2.32 ppm, a Cp-H signal at 1.92
ppm, and an α-Cp signal at -1.84 ppm. These signals are found in a 4:10:4 proton ratio,
respectively.
15
UV-Vis NIR and MCD Spectra:
All UV-Vis NIR and MCD spectra are shown below describing compounds 1,2,
and 3 (Fig. 10). The MCD spectrum of the parent complex 1 contains three Faraday A-
terms centered at 426 nm, 562 nm, and 601 nm, all of which correspond to the three most
intense bands in the UV-Vis NIR spectrum and confirm its effective four-fold symmetry).
The axial coordination of one ferrocene substituent results in a red shift (a shift to lower
energy), of the Soret and Q-bands in the UV-Vis NIR spectra. This can be related to the
slight increase in porphyrin core non-planarity. Diferrocene substitution into the axial
positions shows very similar results, although the porphyrin core is more planar than the
mono-substituted complex.
The substitution of ferrocene for chlorine lowers the molecular symmetry of the
complex to Ci or Cs. Despite this, the MCD spectra for both are dominated by three
Faraday pseudo A-terms centered at 435, 574, and 614 nm for mono and 436, 449, and
633 nm for the di-substituted. This probably reflects free rotation of the ferrocene groups
around the Sn-Cipso(Fc) bond. All Faraday A- and pseudo A-terms shown in the MCD
spectra are centered close to the absorption maxima with negative components located at
lower energies. According to the perimeter model25, this observation suggests that the
∆HOMO > ∆LUMO (∆HOMO is the energy difference between the two highest
occupied π-orbitals centered at the porphyrin core and ∆LUMO is the energy difference
between the two lowest energy π*-orbitals centered at the porphyrin core) in agreement
with DFT calculations, which are shown later.
16
Electrochemistry
Cyclic voltammetry (CV), differential pulse voltammetry (DPV), and square
wave voltammetry (SWV) are all particularly useful for rapidly observing redox behavior
over a wide potential range. As electrical current loops from low to high voltage from a
middle point, different oxidation and reduction electron transfer processes can be
identified. The influence created by electrolyte and solvent combinations on electron-
transfer processes and ΔE1/2 values in the multi-nuclear transition-metal complexes are
well-discussed in the literature26. Since the oxidation of the ferrocene substituents in poly-
(ferrocenyl)-containing macrocycles is sensitive to the nature of solvent and electrolyte,26
the redox properties of both the new Sn(IV) porphyrins were investigated by the three
electrochemical methods in dichloromethane (DCM), a low polarity solvent, coupled
with either tetrabutylammonium perchlorate (TBAP) or tetrabutylammonium
tetrakis(perfluorophenyl)borate (TFAB)— non-coordinating electrolytes27.
0
2
4
6
8
400 600 800-9-6-3036
624439
617
574
434
342����
� , M-1 c
m-1
x 15
x 10
x 30
x 15
x 15
x 25
435346
406
428
447 521517
561
592602
630
628
434
435426
453562
556
607647
402
420 431446449
568 596
609
608������
, M-1 c
m-1 T
-1
Wavelength (nm)
Figure 10: UV Vis (top) and MCD (bottom) Spectra of Compounds Cl2SnTPP (1), FcClSnTPP (2), and Fc2SnTPP (3)
17
Electrochemical data for compound 1 has been published in literature. Oxidation
and reduction potentials were found at 1.44V, -0.79V, and -1.25V at 22°C and 1.88V,
1.42V, -0.73V, and -1.15V at a -75°C, respectively28. The lower temperature experiment
displayed the chemical reversibility of the compound better than higher temperature
experiment. These processes describe the electrons being transferred from the porphyrin
core. Compound 2 contains a ferrocene that can be oxidized, as well as the porphyrin
core. Ferrocene’s reversible oxidation is found at -0.03V, exhibiting a ∆E1/2 of 50 mV.
Porphyrin oxidation was detected at 1.22V, with a corresponding reduction peak at -
1.96V. Due to the impurity of the compound, further processes may have been seen, but
are not directly linked to the porphyrin system.
Table 7: Summary of DPV Data for FcClSnTPP (2)
Summary of Electrochemical Differential Pulse Voltammetry
Data for FcClSnTPP
Solvent/Electrolyte Redox Process
P2 P1 Fc+1 P+1
DCM/TFAB 1.96 0.03 1.22
Redox potentials vs (Fc+/Fc), electrolyte concentrations: TBAP = 0.1M;
CV and DPV experiments reveal three reversible oxidation and two reversible
reduction processes in 3. Similar to Fc2GeP systems, the first two closely spaced
oxidations were assigned to single-electron ferrocene-centered processes, while the third
oxidation and both reduction couples are porphyrin core-centered single-electron
processes. Both ferrocene substituents in 3 could be oxidized at lower potentials
compared to ferrocene, while the separation between the first two oxidation waves (250
mV) in 3 is significantly larger than the separation reported for Fc2GeP complexes (160–
180 mV).20
18
Table 8: Summary of DPV Data for Fc2SnTPP (3)
Spectroelectrochemistry:
Spectroelectrochemistry was performed in order to obtain UV-Vis-NIR
spectroscopic signatures of the different electron transfer processes that were seen with
the electrochemistry. Stepwise oxidation was performed in either a dichloromethane and
tetrabutylammonium perchlorate (TBAP) or tetrabutylammonium
tetrakis(perfluorophenyl)borate (TFAB) environment. Initial spectroelectrochemical
oxidation of FcClSnTPP showed a decreasing in intensity of the 430 nm (23255 cm-1).
The four Q-bands found for this compound also varied in their intensity. The Q-Band at
547 nm (18281 cm-1) decreased, while the 569 nm (17575 cm-1), where the 591 nm
(16920 cm-1) Q-band decreased, and the 614 nm (16287 cm-1) Q-band increased. The
Soret band and Q-bands all exhibited a red shift in energies from their initial intensities.
This change signifies the appearance of the [FcClSnTPP]+ signature, confirming a single
electron transfer. Further oxidation exhibited decomposition of the compound under
spectroelectrochemical conditions.
Summary of Electrochemical Differential Pulse Voltammetry Data for Fc2SnTPP
Solvent/Electrolyte Redox Process
P2 P1 Fc+1 Fc+2 P+1
DCM/TFAB 2.21 1.70 0.31 0.07 1.17
Redox potentials vs (Fc+/Fc), electrolyte concentrations: TFAB = 0.09M;
19
Figure 11: Spectroelectrochemical Plot for FcClSnTPP (2); inset spectrum depicts QBand area only
Initial spectroelectrochemical oxidation of Fc2SnTPP showed a decreasing in
intensity of the main portion of the shoulder peaked Soret band at 447 nm (22371 cm-1).
The shoulder area of the Soret, which could be due to slight oxidation before
spectroelectrochemistry was started, shows an increase in intensity at 428 nm (23364 cm-
1). The initial Q-bands oscillate between increasing and decreasing intensity. There is a
rising of intensity at the 583 (17153 cm-1) Q-band, a decreasing of a shoulder at 603 nm
(16584 cm-1), a rising at 630 nm (15873 cm-1), and another decreasing at 654 nm (15291
cm-1). As oxidation continues, the Q-bands continue to change in the same manner, but
the Soret bands double peaks form to one at 435 nm (22988 cm-1). Continued oxidation
displays wavering in the Soret and Q-bands around the same intensities.
20
Figure 12: Spectroelectrochemical Plot for Fc2SnTPP (2); inset spectrum depicts QBand area only
Chemical Oxidations:
Chemical oxidation titrations were performed using either silver trifluoromethyl
sulfonate (AgOTf) or 2, 3-dichloro-5, 6-dicyanobenzoquinone (DDQ) in order to confirm
agreement with the spectroelectrochemical data. Titrations with AgOTf metals are
commonly used as they are good one electron oxidants29. The strength of silver as an
oxidant has been described from mild to strong29, but either way has proven very useful
for these chemical purposes.
In agreement with the spectroelectrochemical data obtained, the formation of the
first UV-Vis-NIR signature of 2, [FcClSnTPP]+, was replicated by using excess additions
21
of AgOTf. Initial Soret band intensity at 435 nm (22989 cm-1) was found to decrease and
blue shift to 430 nm (23256 cm-1). The different Q-Bands found at 547 nm (18281 cm-1),
574 nm (17421 cm-1), and 619 nm (16155 cm-1) all increase, decrease, and decrease,
respectively. A titration with DDQ displayed similar results. With DDQ, the initial Soret
band at 436 nm (22989 cm-1) displays an increasing in intensity, which is opposite than
the other titration, however in its increase it blue shifts, which is like the other titration.
This difference can be due to AgOTf’s ability to react with the compound, whereas DDQ
will oxidize the compound without reaction. The Q- Bands at 573 nm (17542 cm-1), 593
nm (16863 cm-1), and 621 nm (16103 cm-1) also similar changes in their intensities.
Figure 13: Chemical Oxidation Titration using AgCF3SO3 of FcClSnTPP (2); inset spectrum depicts Q-Band area only
22
Figure 14: Chemical Oxidation Titration using DDQ of FcClSnTPP (2); inset spectrum depicts Q-Band area only
Chemical oxidation experiments conducted on 3 proved to be similar to the
spectroelectrochemical transformations shown above. Two key processes were revealed
and found to be associated with the consecutive oxidation of the axial ferrocene
substituents. It should be noted that these results are also similar to those observed in the
Fc2GeTPP system reported earlier.15 Specifically, during the first oxidation, the Soret
band shifts from 447 (22371 cm-1) to 435 nm (22988 cm-1), while the Q-bands also
undergo a blue shift from 592 nm (16892 cm-1) and 630 nm (15873 cm-1) to 569 nm
(17575 cm-1) and 609 nm (16420 cm-1), respectively. During the second oxidation
process, the Soret band undergoes a further blue shift from 435 nm (22988 cm-1) to 426
nm (23474 cm-1), while the Q-bands shift from 569 nm (17575 cm-1) and 609 nm (16420
cm-1) to 559 nm (17889 cm-1) and 604 nm (16566 cm-1), respectively.
23
Figure 15: Chemical Oxidation Titration using AgCF3SO3 of Fc2SnTPP (3); inset spectrum depicts Q-Band area only
The development of an intense inter-valence charge-transfer (IVCT) band in the
NIR region of electronic absorption spectra of poly(ferrocenyl)-containing macrocyclic
complexes under chemical or electrochemical oxidation conditions5,6 has been suggested
for a long time to be indicative of the formation of mixed-valence compounds, where
IVCT characteristics, i.e. intensity, half-width, and absorption energy, were proven to be
useful in characterizing the metal–metal coupling in these systems.5,6 IVCT bands in
poly(ferrocenyl)-containing porphyrins usually appear as strong transitions in the NIR
region.5a,e,6d,e Similar to Fc2GeP systems, however, no intense IVCT band was observed
in the UV-Vis-NIR spectrum of 3+ between 700 and 2650 nm in the
spectroelectrochemistry or chemical oxidations. Such behavior in 3+ and [Fc2GeP]+
24
complexes could be explained on the basis of the electronic structure of 3 compared to
the electronic structures of the other poly-(ferrocenyl)-containing porphyrins with direct
ferrocene–porphyrin bonds.5g Indeed, when ferrocene substituents are directly bonded to
the porphyrin core, MLCT and IVCT transitions could borrow intensity from the
porphyrin-centered Π–π*excitations (as confirmed by TDDFT calculations that are
shown below),30 while in the case of Fc2MP complexes results suggest no mixing
between porphyrin-centered π–π* and MLCT transitions. Therefore, no IVCT band is
found. In the case of FcClSnTPP, where only one metal is involved an IVCT band is also
not found due to the inability to communicate with another metal.
Fluorescence Oxidation Titrations and Quantum Yield:
Studying the fluorescence of either an unsubstituted or substituted ferrocene
molecule proves very interesting. Unsubstituted ferrocene absorption and luminescent
abilities were first examined by Scott and Becker31, who reported that it was very
dependent on the excitation frequency. The axial coordination of the ferrocene
substituents in compounds, such as in both 2 and 3 for example, also affect its fluorescent
properties. When porphyrin electrons are excited from the S0 ground state to the S1
excited state (a π-π* transition), it is thought that the axial ferrocenes electrons fill the
ground state before relaxation—initiating quenching. Indeed, the fluorescence quantum
yields of 5-ferrocenyl-10,15,20-tri(aryl)porphyrins are very low17 and no observable
fluorescence in neutral 5,10-bisferrocenyl-15,20-diphenyl-, 5,15-bisferrocenyl-10,20-
diphenyl-, 5,10,15-trisferrocenyl-20-phenyl-, and 5,10,15,20-tetraferrocenyl-porphyrins
25
was found. Compounds 2 and 3 have unexpected detectable fluorescence, although it is
~10 times smaller when compared to high-emitting ZnTPP.
26
Scheme 2: Oxidation of Ferrocene Unit to Show Emission Scheme
It is speculated that because the ferrocene groups in 2 and 3 are ‘uncoupled’ from
the porphyrin π-system, they cannot quench π–π* transition based fluorescence as
effectively as in the case when ferrocene substituents are directly connected to the
porphyrin core. Similar to the 5-ferrocenyl-10,15,20-tr(aryl)porphyrins, however,
fluorescence intensity of 2+ and 22+ increases dramatically because the oxidation of
ferrocene group results in reduced probability of electron transfer from the iron center
into the photoexcited porphyrin core.22 Oxidation titrations were performed on these
compounds using p-chloranil as the oxidant to examine this idea. It was found that when
electrons are being removed, emission does indeed increase. This capability of these
compounds to be “turned-on” proves useful for chemical sensors (i.e. lasers). For
example, when the compound is oxidized— light is emitted, when it is later reduced—
light is absorbed.
h� h�
-e
-
27
Figure 18: Fluorescence Oxidation Titration using pchloranil of FcClSnTPP (2)
Figure 19: Fluorescence Oxidation Titration using pchloranil of Fc2SnTPP (3)
28
Electronic Structure:
-7
-6
-5
-4
-3
-2
-1
3MOs
Fc
Occ
upie
d
��
����E = 0.435 eVE = 0.606 eV
Cl2SnTPP (1) FcClSnTPP (2)
Uno
ccup
ied
Ene
rgy,
eV
Fc2SnTPP (3)
202, -4.935
203, -3.231
241, -3.742
242, -3.136
280, -3.554
281, -3.119
E = 1.704 eV
��
�
Fc6MOs
]]
Figure 20: Molecular Orbital Energy Diagram of 1, 2, and 3
Density functional theory calculations were performed to gain insight into the
nature of the electronic structures of 1, 2, and 3. Gas-phase geometries were optimized
using BP86 exchange-correlation function full- electron D6DZVP basis set for Sn and 6-
311G(d) basis set for all other atoms. The HOMO-LUMO gap shown in the molecular
orbital energy diagram above shows the energy differences for all three compounds,
compound 1 has the largest gap while compound 3 has the smallest. Molecular orbital
contribution diagrams are also shown below for all compounds in order of ferrocene
substitution. The electronic structures of 2 and 3 feature several are very similar. Similar
29
to other ferrocenyl-containing porphyrins, the HOMO to HOMO-3 for 2 and HOMO to
HOMO-5 for 3 are predominantly ferrocene centered MOs, while the occupied π-orbitals
centered at the porphyrin core have significantly lower energies. The LUMO to
LUMO+1 with all compounds are predominantly porphyrin core-centered π* orbitals
being doubly degenerate in the case of 1. The presence of six ferrocene-based orbitals in
3 between porphyrin π and π* MOs provides numerous possibilities for the MLCT (Fe -
Por) bands with lower energy than the Q-band(π-π* transition). Selected molecular
orbital images are also shown below for all tin compounds.
Figure 21: Molecular Orbital Contribution Diagram of Cl2SnTPP (1)
192
194
196
198
200
202
204
206
208
210
212
0 10 20 30 40 50 60 70 80 90 100
% Composition
Orb
ital N
umbe
r
Cl Sn Por
Occ.
Unocc.
30
232
234
236
238
240
242
244
246
248
250
252
0 10 20 30 40 50 60 70 80 90 100
% Composition
Orb
ital N
umbe
r
Cl Fe Cp Sn Por
Occ.
Unocc.
Figure 22: Molecular Orbital Contribution Diagram of FcClSnTPP (2)
270
272
274
276
278
280
282
284
286
288
290
0 10 20 30 40 50 60 70 80 90 100
% Composition
Orb
ital N
umbe
r
Fe Cp Sn Por
Occ.
Unocc.
Figure 23: Molecular Orbital Contribution Diagram of Fc2SnTPP (3)
Cl2SnTPP (1)
LUMO+1 LUMO+ HOMO HOMO-1
31
FcClSnTPP (2)
LUMO+1 LUMO HOMO HOMO-1
HOMO-2 HOMO-3 HOMO-4 HOMO-5
Fc2SnTPP (3)
LUMO+1 LUMO HOMO HOMO-1
HOMO-2 HOMO-3 HOMO-4 HOMO-5
32
HOMO-6 HOMO-7
Figure 24: Selected Molecular Orbital Pictures of 1, 2, and 3
Hypotheses from above where were further tested by a TDDFT approach, which
accurately predicts the energies of π–π* and MLCT transitions in ferrocene-containing
compounds, porphyrins, and phthalocyanines.32 TDDFT calculations on 1, 2, and 3 result
in a reasonable agreement between theory and experiment. However, TDDFT predicts
only π–π* transitions in the 250–900 nm region, while the energies of all MLCT bands in
3 were predicted in the ~2000–2500 nm energy envelope.
33
Figure 25: Time Dependent Density Function Theory Plots of 1, 2, and 3; Experimental spectra are shown in solid lines, while TDDFT states are presented by vertical red bars
Conclusions:
Four new Sn(IV) ferrocene-containing porphyrins were successfully prepared and
characterized by 1H NMR, UV-Vis, and MCD spectroscopy. New and interesting axially-
substituted crystal structures of all target compounds were confirmed by single crystal X-
ray analysis. The redox properties of these compounds were also examined. It was found
that compounds 2 and 3 displayed unexpected initial fluorescence (unquenched). When
undergoing oxidation, however, the emissions of 2 and 3 increased as expected. The
capability of these compounds to be “turned-on” is of extreme importance and therefore this
property is highly sought after for chemical sensing applications.
34
Part 2 - Indium(III) Poly-Ferrocenyl Containing Porphyrins
Introduction:
Compounds containing transition metals, that exhibit long-range metal-metal
coupling, have been intensely studied for their interesting fundamental properties (i.e.
multiredox processes, magnetic coupling, and unpaired electron density migration).
These properties make them potentially functional in nano-sized multinuclear switchable
arrays, which are attractive from the practical standpoint (molecular electronics, quantum
cellular automata, opto-electronic materials for application in high-speed photonic or
redox devices).15,33 Polynuclear transition metal complexes that can demonstrate mixed-
valence states, particularly those containing ferrocene, are responsible for the above.1
Ferrocene’s role is to be easily oxidized and later reduced, and this makes it a very
interesting ligand.
Meso-ferrocenyl substituted porphyrins have been studied and proven to be very
promising in terms of the properties and applications listed above.5e,6d,34,,35,36 Compounds
such as these, 5,10,15,20-tetraferrocenyl porphyrins, were first prepared in 197737, and
their synthesis that has been much improved upon since. 5e,38 Tetraferrocenyl porphyrins
with different central metal substituents have also been intensely studied;6d,36,39 these
metals include: Co, Ni, and Zn.5e,6d In this chapter, new 5,10,15,20-tetraferrocenyl
porphyrins with an indium metal central substituent are reported.
Indium is either found in a +1 or +3 oxidation state. Properties of indium have
been under deep investigation since 1924, when W.S. Murray found that its addition to
different metals improved the qualities of the resulting alloys.40 Indium’s usage in
organometallic chemistry was first examined with by Rieke and coworkers, when they
35
used it for a metal-mediated Reformatsky type reaction.41 Indium is often used
industrially; for example, in bearings, platings, and alloys.40 Indium (III) addition into
porphyrin systems contributes interesting qualities to the molecular structure, especially
for undergoing redox activity because itself does not become oxidized.
The new indium metallated porphyrins have been evaluated for their molecular
structure and redox properties. It has been found that with multiple ferrocene groups,
these compounds have controlled redox behaviors that can assist with the chemical
reversibility needed in molecular electronics.
Synthesis:
Three new In3+ polyferrocenyl containing porphyrins are presented in this work
and were prepared by the following syntheses. As can be seen in Scheme 2, metal-free
5,10,15,20-tetraferrocenyl porphyrin is used as the parent precursor. To this porphyrin
system, indium metal has been introduced to the central position.
Five-coordinate indium is bonded to four nitrogens within the porphyrin core; the
extra axial position allows for an additional substituent. The first indium compound
presented here has an axial chloride group. In the past, reactions used to create indium-
chloro compounds took place in glacial acetic acid media and for long periods of time41
Due to the sensitivity of the ferrocene groups involved in parent H2TFcP compound, a
new method was developed for the preparation of ClInTFcP complex (6). In the new
method, metal-free 5,10,15,20-tetraferrocenyl porphyrin was treated with LiN(SiMe3)2
and InCl3 in dry THF solvent, where it was refluxed for three hours (Scheme 3; see
36
experimental section for more detailed syntheses). The new synthesis gives >50% yield.
Compound 6 is the precursor to two other new compounds.
N
NH N
HN
Fe
Fe
Fe
Fe1) LiN(SiMe3)2, reflux 15 min2) InCl3, reflux 3 h, UV-Vis control N
N N
N
In
Cl
Fe
Fe
Fe
Fe
Scheme 3: Preparation of ClInTFcP (6)
A substitution of the chloro-substituent for a hydroxo-group could be achieved by
washing compound 6 three times with 2M NaOH and distilled water (Scheme 4). This
procedure was adapted from a technique used by P.G. Parzuchowski and coworkers.43
After thorough washing with both the base and water, the product is recrystallized with
hexanes. Impurities are removed via centrifugation. This particular reaction presents very
low yields (14%). This could be due to inefficient separation in the washing steps and
also with centrifuging.
N
N N
N
In
Cl
Fe
Fe
Fe
FeH2O /NaOH
N
N N
N
In
OH
Fe
Fe
Fe
Fe CH2Cl2
Scheme 4: Preparation of HOInTFcP (7)
6
6 7
37
Compound 6 also could be used for the preparation of the organometallic
compound 8 (FcInTFcP). The same synthesis as used previously for the Sn(IV)
complexes (Scheme 5) is utilized by again substituting a ferrocene group for the chlorine
using a ferrocene-lithium salt18. This reaction gives very stable compounds and also very
high reaction yields—at above 50%.
N
N N
N
InCl
Fe
Fe
Fe
FeN
N N
N
In
Fe
Fe
Fe
Fe
Fe
FcLi, toluene/ether
r.t. 30 min
Scheme 5: Preparation of FcInTFcP (8)
X-ray Crystal Structures:
Figure 26: Crystal Structure of ClInTFcP (6)
6 8
38
Figure 27: Crystal Structure of FcInTFcP (8)
Crystal structures of 6 and 8 are shown above in Figures 26 and 27. Both
compounds were crystallized in triclinic symmetry (P-1 space group) and contain two
molecules per unit cell. Indium metal is a five coordinate metal, thus it is located above
the porphyrin system. Corresponding distances from Indium to the C7-C8-C17-C18
porphyrin plane are 0.602 Å and and 0.734 Å for 6 and 8, respectively. Bond length
differences can be explained in terms of size of substituents. For example, ferrocene’s
larger size pulls indium out of the porphyrin plane more than the smaller chloride.
Indium metal in both compounds is coordinated to four nitrogens in the porphyrin
system and either a chloride anion (6) or the carbon atoms of the ferrocenyl ligand (8).
Corresponding In-N bond distances lie in the regions 2.146(2)-2.171(2) Å for 6 and
39
2.183(4)-2.218(4) Å for 8, while In-Cl is 2.394(1) Å which are comparable to the
distances observed for similar compounds (2.369(2)44, 2.374(1) Å45, 2.360(2) Å46). The
distances found for In-C in 8 is 2.152(6) Å and is very close to that for CH3InTPP
(2.1328(2) Å).47
Table 9: Table of Selected Bond Lengths (Å ) and Angles (°) for Compound 6
Selected Bond Lengths (Å) and Angles (°) for 6 In(1A)-N(1) 2.146(2) In(1A)-N(4) 2.153(2) In(1A)-N(2) 2.158(2) In(1A)-Cl(1A) 2.394(10) In(1A)-N(3) 2.171(3) N-In(1A)-Cl 99.30-112.85 (7)
Table 10: Table of Selected Bond Lengths (Å ) and Angles (°) for Compound 8
Selected Bond Lengths (Å) and Angles (°) for 6 In(1)-N(1) 2.191(4) In(1)-N(4) 2.213(4) In(1)-N(2) 2.218(4) In(1)-C(61) 2.151(6) In(1)-N(3) 2.183(4) C(61)-In(1)-N 106.30(19)-113.85(19)
An interesting feature of these compounds is their equivalence in NMR
spectroscopy pertaining to the ferrocene substituents attached to the porphyrin core.
Indeed, in each compound’s 1H NMR spectra, the three separate signals appear for the
ferrocene substituent, (α-Cp, β-Cp, and Cp-H protons) confirming that the ferrocene
substituents are free to rotate around single C-C double bonds and probably adopt
different conformations in solid state. It is also important to say that ClInTPP porphyrin
does not reveal such behavior or splitting of the ortho- protons of the phenyl ring.44 The
porphyrin bound equatorial ferrocenes can be rotated up or down with respect to the
porphyrin system, which can be assigned α or β, respectively. Compound 6 adopts an
α,α,β,β conformation of ferrocene substituents, while compound 8 has an unpredictable
α,α,α,α conformation. It is of interest to note that the parent compound, H2TFcP, exhibits
40
a more expected α,β,α,β conformation.48 Such conformation, on the other hand, cannot be
considered favorable because of significant distortion of the porphyrin core that has not
been observed for 6 and 8. Also, the ferrocene molecules with the same conformation
(α,α or β,β) can affect on the β-pyrrolic carbon atoms, pushing them to opposite
directions (angles 162.15°-178.94°). The conformation of the ferrocenes also dictates a
small distortion of the porphyrin system that can be considered an “S” (6) and “C” curve
(8). Compound 6 crystallized with solvent molecules of toluene (one per molecule
ClInTFcP) which forms π-π interactions. Indeed, in the structure of 8 two molecules form
a supramolecular dimer through π-π interactions between aromatic macrocycles. Such π-π
stacking also exists between Cp rings of σ-bonded ferrocenes (Cpaxial-Cpequatorial = 3.370
Å). Two FcInTFcP molecules can be associated by π-π stacking and related through a
center of inversion, where the In-C bond becomes shielded towards substitution at the
indium metal. Packing diagrams for 6 and 8 are shown below in Figures 28 and 29.
Figure 28: Zig-Zag Packing of Complex 6
41
Figure 29: π-π Stacking of Complex 8
Table 11: Selected Crystallographic Parameters of 6 and 8
Selected Crystallographic Parameters of 6 and 8
6 8 Empirical formula C70.91 H62.75 Cl Fe4 In N4 C70H53Fe5InN4
Formula weight 1344.59 1344.23 Crystal system Triclinic Triclinic Space group, Z P-1, 2 P-1, 2 a (Å) 11.2415(3) 13.709 b (Å) 15.3866(3) 14.553 c (Å) 16.2741(11) 15.818
α (°) 82.613(6) 69.95 β (°) 81.185(6) 76.12 γ (°) 76.854(5) 63.42 Volume (Å3) 2695.9(2) 2637.3 ρcalc(g/cm3) 1.656 1.693 μ(Mo-Kα)(mm-1) 1.573 1.820 θmax(°) 27.48 25.04 Reflections collected/unique, Rint
3246 / 12287, 0.0380
26966 / 9252, 0.0879
Data/restraints/parameters 12287 / 0 / 714 9252 / 0 / 721 GooF(F2) 1.132 1.010 R1a, wR2b(F2>2σ(F2)) 0.0391, 0.0967 0.0549, 0.1274 R1a, wR2b (all data) 0.0437, 0.0987 0.0810, 0.1435 Δρmax/Δρmin (e/Å3) 0.595/ -0.450 1.171/ -0.953 aR1(F) =Σ||Fo| - |Fc||/Σ|Fo|. bwR2(F2) = {Σ[w(Fo2 – Fc2)2]/Σw(Fo2)2]}1/2.
w1/2 = [1.0/(2.14*t[0]'(x)+2.62*t[1]'(x)+0.644*t[2]'(x))]1/2,x = Fo/Fomax
42
NMR Spectra:
The H2TFcP precursor itself exhibits five different proton signals. The porphyrin
ring, composed of four pyrroles, contributes two of those signals, one of them being from
its β-pyrrolic position. This proton lies furthest downfield. The second one originating
from the porphyrin core is from inner NH-pyrrolic protons, which are found in the
completely opposite updield direction due to π- system ring current5g. The last three of
the five signals displayed come from the ferrocene units connected to the meso-
substituted porphyrin. Like with the Sn(IV) compounds discussed above, ferrocene again
contributes alpha (α) proton signal, a beta (β) proton signal, and a “Cp-H” signal to the
spectra.
With all the new tetraferrocenyl porphyrins reported here, the metal indium was
introduced into the porphyrin ring. Doing so eliminates the inner pyrrolic proton signals
from the spectrum. All new compounds, varying only by their axial substituent, contain
roughly the same central set of signals. Chemical shifts for the ClInTFcP compound were
reported at 4.25 (Cp-H), 4.86 (β-Cp), 5.54 (α-Cp), and 10.02 (β-pyrrole) ppm with respect to
a tetramethylsilane (TMS) standard. All peaks were found as singlets (for all In(III)
compounds), for which there are no coupling constants.5g
43
Compound 7 contains all the same signals as 6, but also exhibits an extra signal at
-5.37 ppm for the O-H proton. The extreme upfield displacement is attributable to the π-
system ring current running through the center of the porphyrin. Signals were reported at
4.36 (Cp-H), 4.86 (β-Cp), 5.54 (α-Cp), and 10.02 (β-pyrrole) ppm with respect to the
tetramethylsilane (TMS) standard.
Figure 30: 1H NMR Spectrum of ClInTFcP (6)
Figure 31: 1H NMR Spectrum of OHInTFcP (7)
Cp
α-Cp β-Cp
β-Pyrrole
α-Pyrrole
Cmeso
Cipso
N
N N
N
In
Cl
Fe
Fe
Fe
Fe
α-Cp
β-Pyrrole
α-Pyrrole
Cmeso
Cipso
N
N N
N
In
OH
Fe
Fe
Fe
Fe
Cp
β-Cp
44
Compound 8, FcInTFcP, reveals three additional proton signals its spectrum, All
three come from the ferrocene group axially bound to indium. Now, there are two types of
alpha protons, beta protons, and also Cp-H protons. However, the protons from the axial
ferrocene lay further upfield—again due to ring current. Chemical shifts were confirmed
by two-dimensional GCOSY NMR and are reported here as: 0.85 (α-Cp axial Fc), 2.49 (Cp-
Haxial Fc), 2.99 (β-Cpaxial Fc), 4.15 (Cpeq. Fc), 4.81 (β-Cpeq. Fc), 5.54 (α-Cpeq. Fc), 9.90 (β-
Pyrrole) with respect to a tetramethylsilane (TMS) standard.
45
Figure 33: GCOSY NMR Spectrum of FcInTFcP (8)
Variable temperature NMR was performed on ClInTFcP and FcInTFcP to
examine the barrier of rotation the equatorial ferrocenes face when in contact with the β-
pyrrolic protons and the center axial substituent. Through the use of this dynamic type of
NMR, the measurements of activation energies can be performed to gain insight into
these processes. Through a gradual decreasing in temperature, proton splitting was
evaluated. With compound 8, the β-pyrrolic protons split between the temperatures 183-
174 K due to the ferrocenes locking in place. Coalescense for this compound is 199 K.
Off of this value, the free energy of activation for this compound was estimated to be
35.7 kJ/mol
α-Cp (axial)
β-Cp (axial)
Cp-H (axial)
46
The indium-chloro compound’s β-pyrrolic protons did not split with the decrease
in temperatures. This study displayed broadening of the downfield β-pyrrolic signal at
low temperatures—suggesting that the ferrocene moieties were at or around coalescence
temperature. An exact temperature for coalescence could not be obtained due to the
freezing point of the solvent.
199
K183
178
174
298
253
K
213
K
298 K
253 K
229 K
185 K
180 K
177 K
47
Previous work with both tetraphenyl porphyrins49and tetraferrocenyl
porphyrins5eshow that the temperature at which rotation is fast on the NMR time scale
may depend on the metal; in addition, it has been found that substituent rotation also
requires significant distortion of the porphyrin49. Estimated activation energies for
previously prepared metallated tetraferrocenyl porphyrins increase in the order of Ni < H2
< Zn.6d When in comparison with the new indium metallated porphyrins, the new
compounds fall in the following order: InCl < Ni <H2 < Zn < InFc. Although indium is
slightly bigger than both nickel and zinc, the degree of planarity found within the
tetraferrocenyl porphyrin is quite different. This can be due to the coordination
capabilities of the metal and the overall effect they have on the molecule.
As for 13C NMR spectroscopy, the same assignments can be assigned to the
carbons that harbor the protons already described. There are three new species to assign
however. These include, a Cpipso carbon which is the carbon that belongs to ferrocene in
the bond that bonds it to the porphyrin ring. The porphyrin core carbon that is also part of
this bond is labeled the Cmeso carbon. Meso-substituted “connotation” comes from
substituents bonded to this carbon. An α-pyrrolic carbon is also seen. Chemical shifts for
the ClInTFcP compound are 69.29 (β-Cp), 70.63 (Cp), 76.02 (α-Cp), 89.99 (Cpipso),
120.30 (Cmeso), 131.62 (β-Pyrrole), and 149.28 ppm (α-Pyrrole). These values are very
similar to the shifts reported for H2TFcP. Chemical shifts for OHInTFcP are very similar
to the ones just discussed. They are reported as such: 69.05 (β-Cp), 71.01 (Cp), 78.09 (α-
Cp), 90.71 (Cpipso), 120.02 (Cmeso), 131.13 (β-Pyrrole), and 150.03 ppm (α-Pyrrole).
48
Cp
αCp βCp
βPyrrole
αPyrrole
Cmeso
Cipso
N
N N
N
In
Cl
Fe
Fe
Fe
Fe
αCp
βPyrrole
αPyrrole
Cmeso
Cipso
N
N N
N
In
OH
Fe
Fe
Fe
Fe
Cp
βCp
49
The same designated proton areas in the FcInTFcP compound were seen as
carbons, as well as the α-pyrrole carbon, the Cmeso carbon, and the Cpipso. Peak
assignments were verified using two-dimensional HMQC NMR. They were reported as:
66.65 (Cpaxial Fc), 67.87 (β-Cpaxial Fc), 69.16 (β-Cpeq. Fc), 70.85 (Cpeq. Fc), 71.06 (α-Cpaxial Fc),
72.52 (α-Cpeq. Fc), 90.36 (Cpipso), 119.36 (Cmeso), 132.14 (β-Pyrrole), and 149.31 (α-Pyrrole).
αCpaxial
βCpaxial CpHaxial
βCpeq.
Cpeq.
αCpeq.
Figure 38: 13
C NMR Spectrum of FcInTFcP (8)
50
UV-Vis NIR and MCD data:
The UV-Vis NIR/MCD spectra for ClInTFcP (Fig 40), OHInTFcP (Fig 41), and
FcInTFcP (Fig 42) are shown below. Each exhibit an intense Soret band located at 437
nm, 437 nm, and 442 nm respectively. Each also display single Q-Bands at 719 nm, 712
nm, and 724 nm correspondingly. These Soret bands are represented in their
corresponding MCD specta by Faraday pseudo-A terms at 439, 439, and 443 nm,
respectively. The Q-Bands are also represented by Faraday pseudo A-terms at 716, 713,
and 722 nm, correspondingly. The precursor to all of these compounds, H2TFcP, exhibits
its Soret band at 433 nm and two Q-bands at 664 nm and 728 nm. The corresponding
MCD spectrum for H2TFcP also exhibits an Faraday pseudo A-term for the Soret band;
however, the Q-Bands are represented as negative and positive Faraday B-terms because
of the lower effective symmetry. Consistency of Faraday Pseudo A-terms found among
all three indium compounds indicates that all three new compounds exhibit double
degeneracy in their excited state.
Figure 40: UV-Vis and MCD Spectrum of Compound 6
51
Figure 42: UV Vis and MCD Spectrum of Compound 8
Figure 41: UVVis and MCD Spectrum of Compound 7
52
Electrochemistry
Similar to the tin(IV) compounds discussed previously, cyclic voltammetry (CV),
differential pulse voltammetry (DPV), and square wave voltammetry (SWV) were used
to evaluate the redox capabilities of the new indium compounds 6-8. Again, it is very
useful for rapidly observing redox behavior over a wide potential range. Before it was
interesting to observe the redox properties of the axial substituents, now there are four
ferrocenyl units connected to the porphyrin which may or may not exhibit slightly
different behavior.
Figure 43: Electrochemical Plots for Compounds 6, 7, and 8; Left legend corresponds to red CV data, while
the right legend corresponds to blue DPV data
53
The redox behavior of InClTFcP was studied by methods introduced above, using
dichloromethane as the solvent and tetrabutylammonium tetrakis(perfluorophenyl)borate
(TFAB) as the electrolyte. CV and DPV results are shown in the Figure 43 above. DPV
shows five oxidation processes, with one of them being irreversible, and two reversible
reduction processes. Found in the CV portion are two very close reversible oxidation
processes with a ΔE1/2 difference between the first and second oxidation waves found to
be 229 mV. Out of these two processes, indicated by peaks, one is single and very
prominent, while the other is broader and could actually be three very close signals. The
same idea can be seen with the DPV data. The reduction waves were found at -2.016 V
and -1.678 V and were assigned to the porphyrin macrocycle. Electron transfer is a result
of communication between redox active centers.
Typically each peak, whether CV or DPV, would indicate a single electron
transfer process. For the broader peaks, it can be thought that single electron transfers are
occurring very rapidly after each other. Deconvolution was perfomed on the oxidation
processes found by differential pulse voltammetry; the results of which can be seen in the
table below.
Table 12: Summary of Electrochemical DPV Data for Compound 6
Summary of Electrochemical Differential Pulse Voltammetry Data for ClInTFcP
Solvent/Electrolyte Redox Process P-2 P-1 Fc+1 Fc+2 Fc+3 Fc+4 P+1
DCM/TFAB -2.016 -1.678 0.050 0.206 0.276 0.360 - Data Deconvolution - - 0.059 0.221 0.280 0.360 -
Redox potentials vs (Fc+/Fc), electrolyte concentrations: TFAB = 0.09M;
The redox behavior of OHInTFcP reports four reversible oxidation processes and
two reversible reduction processes. On the CV portion, two reversible oxidation
54
processes can be observed, as well as two reversible reductions. Similar to compound 6
discussed above, each oxidation peak, whether found in the CV or DPV, is again
attributed to single-electron transfers. Again a very prominent first peak is shown,
followed by a broader peak. The ΔE1/2 difference between the first and second oxidation
waves was found to be 265 mV. This value is just a little bit higher than with 6,
suggesting that the removal of an electron requires more energy, which it is then followed
by the loss of two additional electrons. The reduction waves were found at ~-2.062
mV and ~-1.703 mV and were again assigned to the porphyrin macrocycle.
Deconvolution was also performed for this compound.
Table 13: Summary of Electrochemical DPV Data for Compound 7
Summary of Electrochemical Differential Pulse Voltammetry Data for OHInTFcP
Solvent/Electrolyte Redox Process P-2 P-1 Fc+1 Fc+2 Fc+3 Fc+4 P+1
DCM/TFAB -2.062 -1.703 0.020 0.209 0.303 0.387 - Data Deconvolution - - 0.022 0.196 0.317 0.421 -
Redox potentials vs (Fc+/Fc), electrolyte concentrations: TFAB = 0.09M;
The unique FcInTFcP compound reports 6 oxidation processes, one irreversible
and two reversible reduction processes. Both in CV and DPV, the five reversible
processes can be observed; these processes were also evaluated through deconvolution.
Again, the broadness of the last two oxidation peaks on the CV portion of the spectrum
above indicates consecutive electron losses.
55
Table 14: Summary of Electrochemical DPV Data for Compound 8
Spectroelectrochemistry
Spectroelectrochemistry was also performed on the new poly(ferrocenyl)
containing compounds in order to obtain a visual of the UV-Vis-NIR spectroscopic
signatures found in the electrochemistry. Stepwise oxidation was performed in a
DCM/TFAB environment. Inter-valence charge transfer bands (IVCT) were found within
the NIR region.
Initial spectroelectrochemical oxidation of ClInTFcP showed a decreasing in
intensity and a red shift of the 437 nm (22883 cm-1) Soret band to 442 nm (22624 cm-1),
as well as a decreasing intensity of the 717 nm (13947 cm-1) Q-Band. At this time, an
IVCT band at approximately 945 nm (10582 cm-1) rose, confirming the appearance of a
mixed valency product—[ClInTFcP]+. Continuing oxidation, the Soret band here shifted
from 442 nm (22624 cm-1) to 477 nm (20964 cm-1). There was also the rising of another
NIR band at ~1184 (~8445 cm-1) nm. This new IVCT band is assigned to the mixture of
[ClInTFcP]2+ and [ClInTFcP]3+ due to the wide nature of the new band and the unclear
falling of the first NIR band. Like the electrochemisty suggests, this could confirm the
possibility of multiple electrons being transferred very quickly after one another. When
continuing oxidation, all areas of the spectrum displayed a decreasing of intensity. This
Summary of Electrochemical Differential Pulse Voltammetry Data for FcInTFcP
Solvent/Electrolyte Redox Process P-2 P-1 Fc+1 Fc+2 Fc+3 Fc+4 Fc+5 P+1
DCM/TFAB - - -0.127 0.115 0.263 0337 0.457 - Data Deconvolution - - -0.124 0.114 0.256 0.353 0.456 -
Redox potentials vs (Fc+/Fc), electrolyte concentrations: TFAB = 0.09M;
56
either indicates that a completely oxidized species was obtained or decomposition of
compound under electrochemical conditions.
Figure: 44: Spectroelectrochemical Titration Plot for Complex 6; inset spectrum depicts IVCT area only
The spectroelectrochemical oxidation of OHInTFcP showed amazing similarity to
that of ClInTFcP. First, exhibiting a decreasing in intensity and a red shift of the 437 nm
(22883 cm-1) Soret band to 475 nm (21052 cm-1), as well as a decreasing intensity of the
712 nm (14045 cm-1) Q-Band. An IVCT band also rose at this time around 938 nm
(10660 cm-1), confirming mixed valency of [OHInTFcP]+. Continuing oxidation, the
Soret band at 475 nm remained constant and the Q-band further decreased. There was
also the rising of another NIR band at ~1161 nm (8613 cm-1). This new IVCT band is
assigned to the mixture of [OHInTFcP]2+ and [OHInTFcP]3+ due to the wide nature of the
57
new band. There was also simultaneous falling of the first IVCT band. Much like
compound 6, further electron transfer processes were not obtained.
Figure 45: Spectroelectrochemical Titration Plot for Complex 7; inset spectrum depicts IVCT area only
Spectroelectrochemical oxidations of the five ferrocene FcInTFcP first displayed
the decreasing in intensity and a red shift of the 444 nm (22522 cm-1) Soret band. The
single Q-Band lying at 724 nm (13812 cm-1) also decreased at this time. An IVCT band
did not rise at this time. Due to the fact that an inter-valence charge transfer band was not
visible in the first process hints the possibility that the axial ferrocene was oxidized first.
This was later confirmed by density functional theory (discussion follows). Further
anodic oxidation gave rise to a first IVCT band. This band appeared in approximately the
same region as the two compounds tested before it at ~950 nm (10526 cm-1). At this time,
58
the Soret band and Q-bands further decreased in their absorbance intensity. As
spectroelectrochemical oxidation continued the Soret and Q-Band intensity remained
constant, while the first IVCT band fell and another arose around 1185 nm (8438 cm-1).
Further chemical signatures were not found.
Figure 46: Spectroelectrochemical Titration Plot for Complex 8; inset spectrum depicts IVCT area only
Overall, the spectroelectrochemical experiments performed generated the
spectroscopic signatures of at least three mixed-valence cations ([XTFcP]+, [XTFcP]2+,
and [XTFcP]3+, with X= Cl, OH, or Fc). In some cases [XTFcP]2+ and [XTFcP]3+ may have
been combined. With FcInTFcP, a combined [XTFcP]3+ and [XTFcP]4+ may be present,
but this is only a hypothesis. Each compound displays characteristic IVCT bands in NIR
59
region of UV-Vis-NIR spectra. Each next successful removal of the electron from the
mixed-valence complexes results in a low-energy shift of this IVCT band.
Chemical Oxidation:
Knowing that at least two of each of the new indium porphyrin UV-Vis-NIR
spectroscopic signatures can be obtained through spectroelectrochemical experiments, it
is interesting to observe the chemical oxidation of each. Chemical oxidation titrations
were again performed using excess of silver trifluoromethyl sulfonate (AgOTf) and one
equivalent additions of 2, 3-dichloro-5, 6-dicyanobenzoquinone (DDQ).
In agreement with the spectroelectrochemical data obtained for ClInTFcP, the
first UV-Vis-NIR signature, [ClInTFcP]+, was replicated by the addition of excess
AgOTf, producing an IVCT band at ~938 nm (10660 cm-1). Also observed for the
formation of [ClInTFcP]+ was a decrease in Soret and Q-band intensity. Upon additional
oxidation, complexes [ClInTFcP]2+ and [ClInTFcP]3+ were observed the rise of a second
broad IVCT band at 1041 nm (9606 cm-1). The continuous red shift of the Soret band
through continuous oxidation was also in agreement with the spectroelectrochemistry.
The oxidation of ClInTFcP using DDQ also displayed correlating results for the
formation of the first oxidation complex [ClInTFcP]+. Here, there was consistent
decreasing of both the 437 nm Soret band and 717 nm Q-Band, as well as an increasing
of a ~952 nm NIR band. Any further complex formations were inconclusive.
60
Figure 47: Chemical Oxidation Titration using AgCF3SO3 Plot of Compound 6; inset spectrum depicts IVCT area only
Figure 48: Chemical Oxidation Titration using DDQ Plot for Compound 6; inset spectrum depicts IVCT area only
61
Chemical oxidation of OHInTFcP using one equivalent additions of DDQ
produced an IVCT band at ~920 nm (10869 cm-1). The formation of [OHInTFcP]+ was
observed by a sharp decrease in Soret band intensity at 437 nm (22883 cm-1) and also of
the Q-band at 710 nm (14084 cm-1). Upon additional oxidation, the probable
[OHInTFcP]2+ and [OHInTFcP]3+ signatures were observed by a decrease of first IVCT
band at and the rise of a second broad IVCT band at 1041 nm (9606 cm-1). The
continuous red shift of the Soret band through continuous oxidation was also in
agreement with the Spectroelectrochemistry. Also with this compound, any further
complex formations were inconclusive.
Figure: 49: Chemical Oxidation Titration using DDQ Plot of Compound 7; inset spectrum depicts IVCT area only
62
Only one chemical signature was able to be obtained for compound 8 using
AgOTf. Here, the initial 442 nm (22624 cm-1) Soret band increases in intensity and blue
shifts. At the same time, the 720 nm (13889 cm-1) Q-Band decreases and no rise of an
inter-valence charge transfer band is apparent. Because there is no IVCT rising, this
indicates the possibility of the axial ferrocene being oxidized first. Upon oxidation, axial
and equatorial ferrocenes would not communicate and transfer electrons between each
other. This idea will be further examined below through using density functional theory
analysis.
Figure: 50: Chemical Oxidation Titration using AgOTf Plot of Compound 8
The Hush method 2,50 is typically used for the analysis of experimental data in
mixed-valence compounds. In this case, spectroelectrochemical and chemical oxidation
data was used. Here Gaussian fits were performed on cleanly risen inter-valence charge
transfer bands. All information that is obtained from this technique specifically relates to
63
the properties involved with these bands. Synthetic chemists typically look for the Hab
parameter (the electronic coupling matrix element) and the α parameter (for
delocalization). These parameters can be estimated using equations 1, 2, and crystal
structure calculated distances, and are displayed below in Table 153,4,50 Here νmax is the
energy of the IVCT at band maximum in cm-1, Δν1/2 is the half-width at the band
maximum in cm-1, εmax is the molar extinction coefficient of the IVCT, and rab is the
distance between redox centers in Å. The detection of mixed-valence state behavior is
interesting and indicates that these compounds are potentially useful for molecular
electronics.
��� � 2.05�10�����������∆�����/� Equation 1
� � 4.2�10���∆��
�����
�������� � Equation2
Table 15: Estimated Magnitudes of Hab and α for mixed-valence [ClInTFcP]+, [OHInTFcP]+, and [FcInTFcP]2+; S.E. Spectroelectrochemica
Estimated magnitudes of Hab and α for mixed-valence [ClInTFcP]+, [OHInTFcP]+, and [FcInTFcP]2+ complexes
Compound/Oxidant ν(max) cm-1
ε(max) M-1
Δν1/2 cm-1
raba Å
Hab cm-1
α 103
[ClInTFcP]+ / DDQ 10510 7907 1280 9.760 688.4 0.066
[ClInTFcP]+ / S.E. 10596 7333 1320 9.760 676.0 0.064
[OHInTFcP]+/ DDQ 10982 5373 1234 9.760 569.5 0.052
[OHInTFcP]+/ S.E. 10746 11727 1405 9.760 888.1 0.083
[FcInTFcP]2+ / S.E. 10463 8941 1309 9.205 783.1 0.075
64
Electronic Structure:
Figure 51: Molecular Energy Orbital Diagram of Compounds 6 and 8
Density functional theory calculations were performed to acquire insight into the
nature of the electronic structure and absorption properties of 6 and 8 using the BP86
exchange-correlation functionality and DGDZVP(In)/6311G(d) (all other atoms) basis
set. The molecular orbital energy diagram, shown above, displays that the HOMO-
LUMO gap of 6 to be larger than 8 by roughly 0.53 eV. Compound 8 contains a whole
other ferrocene unit than 6, which gives it additional redox abilities. The prediction as to
which ferrocene will being oxidized first comes into play. The fact that the axial
ferrocene energies lie a bit higher than the equatorial ones for compound 8 hints that the
axial ferrocene is the first to be oxidized.
Molecular orbital contributions of individual moieties for 6 and 8 are represented
graphically in Figures 52 and 53, respectively. The highest occupied orbitals (HOMO,
-4.0
-3.5
-3.0
}InClTFcP InFcTFcP
BP86
Ene
rgy,
eV
}Fca
Fce
65
HOMO-1, HOMO-2, etc.) for 6 are predominantly based on the iron centers, Cp ring
moieties, and the porphyrin core. Again, all ferrocenyl units for this compound are
attached to the meso positions on the ring. The highest MOs for 8 do not contain any
porphyrin contributions, but rather just axial iron and Cp components. Because the
highest HOMO orbitals are the most willing to loose electrons, these contribution
diagrams confirm that when compound 8 undergoes oxidation, its axial ferrocene is the
first to lose an electron.
Figure 52: Molecular Orbital Contribution Diagram of Compound 6
Figure 53: Molecular Orbital Contribution Diagram of Compound 8
298
299
300
301
302
303
304
305
0 10 20 30 40 50 60 70 80 90 100
% Contribution
Orb
ital N
umbe
r
Porp Cl Cp Fe in
Unocc.
Occ.
335
336
337
338
339
340
341
342
0 10 20 30 40 50 60 70 80 90 100
% Contribution
Orb
ital N
umbe
r
AxialCp AxialFe Cp Fe Porph In
Unocc.
Occ.
66
Conclusions:
Three new indium(III) metallated poly-ferrocenyl containing porphyrins have
been successfully prepared and characterized via NMR, UV-Vis, and MCD spectroscopy.
Two new crystal structures have been reported The redox properties were also examined
and mixed-valence behavior was found for all three compounds. Interestingly, it was
found that when ferrocene is σ-bonded to the central metal, it does not participate in
formation of mixed-valence states. The mixed-valence properties shown for these
compounds indicate they would be potentially useful for molecular electronics.
67
Experimental:
Materials:
All reactions were performed under dry argon atmosphere with flame-dried
glassware. All solvents and reagents were purchased from commercial sources and used
without additional purification. Dry toluene was obtained by distillation over sodium and
benzophenone indicator, dry DCM was obtained by distillation over calcium hydride
prior experiments, and dry THF was obtained by distillation over Na/K alloy with
diphenylketone. Silica gel (60 Å, 63-100 μm) needed for column chromatography was
purchased from Dynamic Adsorbents, while basic aluminum oxide (Activity I, 58 Å, 150
mesh) was purchased from Fischer Inc. The compound tetrabutylammonium
tetrakis(pentafluorophenyl)borate (TFAB) was used in anhydrous DCM for
electrochemical studies, after preparation according to literature.25
Synthesis of FcClSnTPP
A 195 mg (0.625 mmol) amount of iodoferrocene was dissolved in 6 mL of dry
diethyl ether at room temperature and then cooled down to -78° using an acetone/dry ice
bath. A 0.3 mL amount of 2.5M solution of butyl lithium in hexane was added drop-wise
to the solution with intensive stirring. After stirring at -78° for 5 min, the cold bath was
removed and the mixture was left to warm up to room temperature. At this time, the
formation of an orange solid (a ferrocene lithium salt) was observed. A suspension of this
salt was added as one portion to a solution of SnCl2TPP (100 mg, 0.125 mmol) in 10 mL
of dry toluene. The new solution immediately became green. The reaction mixture was
68
stirred at room temperature for 24 h and then quenched with 1 mL of distilled water. All
solvents were removed under vacuum and the remaining solid was washed with toluene.
The resulting toluene solution was chromatographed using Al2O3 and several fractions
(monitored by UV-Vis spectroscopy) were collected. The first and second fractions were
eluted using toluene and produced, first, a yellow ferrocene fraction, followed by green
fraction of Fc2SnTPP (3). A third fraction, FcClSnTPP (2), was collected using a 50:50
toluene/ethanol mixture and then pure ethanol. Solvents were removed under vacuum.
Compound (2) was crystallized from a toluene-hexane mixture as a violet powder. Yield:
45 mg (45 %).
1H NMR (500 MHz, CDCl3, TMS), δ (ppm) =: 9.12 (s, 8H, β-pyrrole), 8.38 (d, 4H,
J=11.6 Hz, Ha-Ph), 8.25 (d, 4H, J= 7 Hz, Hb-Ph), 7.83 (t,q, 12H, J= 7.5 Hz, Hc, Hd, and He
-Ph), 2.35 (s, 2H, β-Cp), 2.08 (s, 5H, Cp), -1.17 (s, 2H, α-Cp).
Synthesis of Fc2SnTPP
An amount of 233 mg (0.748 mmol) iodoferrocene was dissolved in 6 mL of dry
diethyl ether at room temperature and then cooled down to -78°C using an acetone/dry
ice bath. An amount of 0.3 mL of 2.5M solution of butyl lithium in hexane was added
drop-wise with intensive stirring. After stirring at -78°C for 5 min, the cold bath was
removed and the mixture was left to warm up to room temperature. The appearance of a
ferrocene-lithium salt was found. A suspension of this was added as one portion to a
solution of SnCl2TPP (100 mg, 0.125 mmol) in 10 mL of dry toluene—which created a
green mixture. This reaction mixture was stirred at room temperature for 24 h and then
quenched with 1 mL of distilled water. All solvents were removed under vacuum and the
69
remaining solid was washed with toluene. The resulting solution was chromatographed
using Al2O3 and a toluene-dichloromethane-triethyl amine (50:50:1) mixture as the
eluent. Several fractions (monitored by UV-Vis spectroscopy) were collected. Ferrocene
was collected as a first fraction, followed by a second green Fc2SnTPP (3) fraction. The
solvent from this fraction was removed under vacuum. Compound (3) was crystallized
from a toluene-hexane as a green powder. Yield: 34 mg (25 %).
1H NMR (500 MHz, CDCl3, TMS), δ (ppm) =: 8.96 (s, 8H, β-pyrrole), 8.30 (s, 8H, o-Ph),
7.79 (s, 12H, m,p-Ph), 2.36 (s, 4H, β-Cp), 1.92 (s, 10H, Cp), -1.84 (s, 4H, α-Cp).
Anal. Calc. (found): C, 69.79 (69.54), H, 4.21 (4.48), N, 5.09 (4.99). Synthesis of Fc(OCH2CH3)SnOEP and Fc2SnOEP
An amount of 259.3 mg (0.831 mmol) iodoferrocene was dissolved in 10 mL of
dry diethyl ether at room temperature and then cooled down to -78°C using an
acetone/dry ice bath. An amount of 0.3 mL of 2.5M solution of butyl lithium in hexane
was added drop-wise with intensive stirring. After stirring at -78°C for 5 min, the cold
bath was removed and the mixture was left to warm up to room temperature. It was found
that a ferrocene lithium salt was formed at this time. The suspension of salt formed was
added as one portion to a solution of SnCl2OEP (100 mg, 0.139 mmol) in 20 ml of dry
toluene and the resulting solution immediately became green. The reaction mixture was
stirred at room temperature for thirty minutes (sheltered from light and controlled by UV-
Vis spectroscopy). The reaction was quenched using 1 mL of distilled water. All solvents
were removed under vacuum and the remaining solid was washed with toluene. The new
70
toluene solution was passed through an aluminum column to eluate a first ferrocene
fraction and a second Fc2SnOEP (5) fraction. Mono-ferrocene octaethyl porphyrin,
Fc(OCH2CH3)SnOEP (4), was also obtained in a third fraction using an ethanol-toluene
mixture (1:1 ratio). The appearance of metal-free octaethyl porphyrin was seen in all
fractions due to de-metallation of the porphyrin system. All solvents were removed under
vacuum. The second and third fractions were recrystallized using a toluene-hexane
system, yielding a light red SnFc2OEP (5) powder and a darker red Fc(OCH2CH3)SnOEP
(4) powder. Due to the high impurity of these compounds, yields could not be calculated.
Synthesis of ClInTFcP
An amount of 800 mg (0.766 mmol) metal-free 5,10,15,20-
tetraferrocenylporphyrin was measured into a 250 mL round bottom flask containing a
magnetic stir-bar. The porphyrin reagent was dissolved in 160 mL dry THF. With
stirring, 1.6 g (0.009 mol) LiN[Si(CH3)3]2 was added and stirred for fifteen minutes. 4.0 g
(0.018 mol) InCl3 was then added and refluxing began for three hours (controlled by UV-
Vis). The mixture was then cooled down, evaporated to dryness under vacuum (0.1-0.5
mmHg), and the solid was set aside for column chromatography. The product was added
to a column packed of silica gel, dichloromethane, and triethylamine. Other eluants used
were straight ethyl acetate, a mixture of dichlomethane and tetrahydrofuran, ethanol, and
also methanol. The first two bands to pass through the column were from unreacted
starting materials—distinct by their light color and small amount. The main product came
out in the third band (confirmed by UV-Vis spectroscopy). Flasks containing the main
71
fraction (Compound (6)) were combined and the solvent was removed under reduced
pressure. Yield: 475 mg (52%)
1H NMR (500 MHz, CDCl3, TMS), δ (ppm) = 4.25 (s, 8H, Cp), 4.86 (s, 8H, β-Cp), 5.54
(s, 20H, α-Cp), 10.02 (s, 4H, β-Pyrrole). 13C NMR (125 MHz, CDCl3, TMS), δ (ppm) =
69.29 (β-Cp), 70.63 (Cp), 76.02 (α-Cp), 89.99 (Cpipso), 120.30 (Cmeso), 131.62 (β-
Pyrrole), 149.28 (α-Pyrrole).
Anal. Calc. (found): C 60.32 (58.79), H 3.71 (3.77), N 4.69 (4.85). MS (APCI, THF, m/z): 1194 [M] + 1231 [M-Cl+THF]+
Synthesis of OHInTFcP
An amount of 30 mg (0.025 mmol) InClTFcP was measured and placed into a 250
mL Erlenmeyer flask and dissolved in dichloromethane. The product was washed three
times with a 2M sodium hydroxide solution. The dark product was then washed three
times with distilled water. The sample was dried with sodium sulfate. Solvent was
removed under reduced pressure. The product was recrystallized using dichloromethane
and hexanes. Centrifugation was used to separate solvent and product. The sample,
Compound (7), was air dried to yield: 4 mg (14%)
1H NMR (500 MHz, CDCl3, TMS), δ (ppm) = 4.36 (s, 8H, Cp), 4.86 (s, 8H, β-Cp), 5.54
(s, 20H, α-Cp), 10.02 (s, 4H, β-Pyrrole). 13C NMR (125 MHz, CDCl3, TMS), δ (ppm) =
69.05 (β-Cp), 71.01 (Cp), 78.09 (α-Cp), 90.71 (Cpipso), 120.02 (Cmeso), 131.13 (β-
Pyrrole), 150.03 (α-Pyrrole).
72
Anal. Calc. (found): C 61.27 (61.48), H 3.86 (4.00), N 4.76 (4.55). APCI MS, THF: 1194 [M+H2O] +, 1230 [M-OH+THF]+
Synthesis of FcInTFcP
An amount of 196.2 mg (0.629 mol) ferrocene iodide was measured into a
Schlenk flask containing a stir bar. A 145 mg (0.121 mmol) amount of InClTFcP was
measured into another Schlenk containing a stir bar. Both flasks were placed under
pressure and flushed with Argon. To the flask containing InClTFcP, 10 mL of toluene
was added. The ferrocene iodide was dissolved in approximately eight milliliters of
diethyl ether. While being flushed with Argon, the temperature of this solution was
brought down using a dry-ice and isopropanol slurry. After temperature was low enough,
0.26 mL butyl lithium was added, stirring began. The new orange FcLi salt was added to
the porphyrin solution via syringe. The reaction mixture was stirred for 45 minutes where
it was then quenched with eight milliliters of distilled water. Solvent was removed under
vacuum (0.1-0.5 mmHg) and solid was set aside for column chromatography. One main
fraction, Compound (8), was obtained. Yield: 94 mg (58%)
1H NMR (500 MHz, THF-d8, TMS), δ (ppm) = 0.85 (s, 2H, α-Cp coordinated Fc), 2.49
(s, 5H, Cp Coordinated Fc), 2.99 (s, 2H, β-Cp Coordinated Fc), 4.15 (s, 20H, Cp
porphyrin Fc), 4.81 (s, 8H, β-Cp porphyrin Fc), 5.54 (s, 8H, α-Cp coordinated Fc), 9.90
(s, 4H, β-Pyrrole). 13C NMR (125 MHz, CDCl3, TMS), δ (ppm) = 66.65 (Cp
Coordinated Fc), 67.87 (β-Cp Coordinated Fc), 69.16 (β-Cp porphyrin Fc), 70.85 (Cp
porphyrin Fc), 71.06 (α-Cp coordinated Fc), 72.52 (α-Cp porphyrin Fc), 90.36 (Cpipso),
73
119.36 (Cmeso), 132.14 (β-Pyrrole), 149.31 (α-Pyrrole).
Anal. Calc. (found): C 62.69 (62.625), H 4.22 (4.245), N 4.12 (3.98). MS (APCI, THF, m/z): 1345 [M]+
Instrumentation:
A Varian Unity INOVA NMR instrument was used to evaluate spectra taken at
500 MHz frequency for protons and 125 MHz for carbons. Each were referenced to TMS
as an internal standard and chemical shifts were recorded in parts per million. All UV-Vis
data was obtained on a JASCO-720 spectrophotometer at room temperature. An OLIS
DCM 17 CD spectropolarimeter with 1.4 T DeSa magnet was used to obtain all MCD
data. Electrochemical measurements were conducted using a CHI620C electrochemical
analyzer utilizing the three-electrode scheme. Either carbon or platinum working,
auxiliary and reference electrodes were used in 0.05 M solution of TFAB (or 0.1 M
TBAP) in DCM with redox potentials corrected using internal standard
(decamethylferrocene) in all cases. Spectroelectrochemical data was collected using a
custom-made 1 mm cell, a working electrode made of platinum mesh, and a 0.15 M
solution of TBAF in DCM. Fluorescence techniques were performed using a Varian Cary
Eclipse Fluorescence Spectrometer. Elemental analysis was performed by Atlantic
Microlab, Inc. in Atlanta, Georgia.
Computational Aspects:
All computations were performed using Gaussian03 software package running
under Windows or UNIX OS52 Molecular orbital contributions were compiled from
74
single point calculations using the VMOdes program.53 TDDFT calculated excitation
energies were found where the lowest 150 singlet excited states had been considered. In
all calculations, Becke’s exchange functional and Pedrew-Wang correlation functional
(BPW91) were used. Wachter’s full-electron basis set was used for iron, DGauss DZDVP
basis set was used for tin atom, while for all other atoms 6-311G(d) basis set was
employed. The percentage of atomic orbital contributions to their respective molecular
orbitals were calculated by using the VMOdes program. In all cases, frequency
calculations were performed to ensure that the optimized structures represent potential
energy surface minima. It has been shown that BPW91 exchange-correlation functional
coupled with the mentioned above basis set could accurately predict MLCT and ���* in
variety of ferrocene-containing compounds, porphyrins, and phthalocyanines.31 The
typical errors for the TDDFT predicted by the mentioned above combination of the
exchange-correlation functional and basis set method are within ~0.1 eV.
X-ray Crystallography
X-ray quality single crystals of 2,3, 4, and 5 were obtained by slow diffusion of
dichloromethane solutions with hexanes. Indium metallated porphyrin crystals, 6 and 8,
were grown from slow diffusion of toluene solutions with pentane. Experimental data for
all compounds except 3 were collected using Rigaku Rapid II X-ray diffractometer with
curved IPDS detector using graphite-monochromatized Mo-Kα radiation (λ = 0.71075
Å), while 3 was collected using SMART APEX II diffractometer with the same radiation.
Structure (2) was solved by Patterson search method using the DIRDIF-200854
program; structure (3) was solved by direct method implemented into SHELXS-9755
75
program; (4), (5), (6) and (8) were solved by direct method using SIR-92 program56. All
missed non hydrogen atoms were located from analysis of a difference Fourier-map and
refined in an isotropic and then in the anisotropic approximations. All aromatic hydrogen
atoms were placed geometrically while hydrogens for methyl group were located from
the difference Fourier-map analysis and were constrained. Thermal displacement
parameters for hydrogen atoms were constrained to the parent atom like Uiso(H) =
1.2Ueq(C) for methylene and aromatic hydrogens including porphyrin system, and Uiso(H)
= 1.5Ueq(C) for methyl group, so called "riding mode" (Ueq=1/3(U11+U22+U33)).
Structures were completely refined using a full-matrix least square method using
SHELXL-97 program.55 The ferrocene subunits in (2) and (4) were found to be
disordered in two different ways: by rotation of unsubstituted cyclopentadiene (Cp) ring
(Fig. 54) and by rotation of the overall ferrocene molecule around the Sn-C bond (Fig.
55). To resolve these disorders a set of geometrical constrains were applied. In the both
cases distances C-C of disordered ferrocene units were constrained to be 1.42 Å within
e.s.d. 0.02 Å and all ferrocene's carbon atoms of unsubstituted Cp ring were constrained
to get planar geometry.
The indium-chloride moiety in (6) was found to be statically disordered
over two positions. Indeed, such disorder is very common for indium contained
macrocycles and induced by five-coordinate central ion where the metal atom lies out of
porphyrin plane. Final refined populations for the two positions were 0.84 and 0.16,
respectively (Fig. 56). In the crystal structure, the position of the minor component of
indium-chloride moiety (In1b-Cl1b) overlaps with the position of the toluene molecule
(C61-C67). For this reason, population of the toluene molecule position less than one and
76
related to the In-Cl part. Two positions were refined together like related variables with
total contribution to a population equal to 1. The best value for R1 was 0.051, but the
difference electron density map analysis revealed five peaks: 3.35, 3.03 2.23, 2.08, 2.05
e-/Å3, that correspond to disordered a pentane molecule (toluene/pentane solvent system
was used for crystallization of the ClInTFcP). It is a very well-known fact that it is very
difficult to correctly model disorder of alkane chains. Unfortunately, such disorder could
not be resolved, so the SQUEEZE procedure was implemented into the PLATON57
program to remove contribution from the disordered area. Afterwards, refinement was
successfully completed with final R1 equals 0.039 and maximum/minimum of electron
density equals 0.6/-0.45 e-/Å3. ORTEP-358for Windows and PLATON/PLUTON57
software were used for visualization of results. All information about the refinement of
crystal structures is presented in Tables 5, 6, and 11 above; the corresponding CIF files
are presented in the Supplemental Section.
Figure 54. The disorder of the ferrocene by rotation around bond Sn-C in (2)
77
Figure 55. Disorder of Cp ring by rotation around Fe atom in (4)
Figure 56. Disorder of ClInTFcP (6) moiety and toluene molecule
78
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Supplemental Material: Inter-Valence Charge Transfer Band Analysis:
Through spectroelectrochemistry, it is possible to obtain spectroscopic signatures
of the different oxidation states possible for a chemical compound. These signatures are
apparent when there is a rising, or falling, of an inter-valence charge transfer band. Due
to investigate the nature of these bands within the different compounds, Hab parameters
were investigated. Using the equations from above and the following fitted Gaussian
plots, the parameters were determined. These parameters can be again seen in Table 11
above.
1.
83
Electrochemical Data Deconvolution Analysis
The typical oxidation of a tetraferrocenyl porphyin consists of four stepwise one
electron transfer processes. All three indium metallated poly (ferrocenyl) containing
porphyrins have very close together electrons transfers—some of which appear as a
single hump and their true electrochemical potentials cannot be seen. To gain better
insight into these processes, Lorentz or Gaussian fitted deconvolution processing was
performed. The plots below display the results.
84
CIF Information for Compound 2:
Crystal data and structure refinement
Empirical formula C56.98 H43.96 Cl Fe N4 Sn Formula weight 994.67 Temperature 123(2) K Wavelength 0.71073 A Crystal system, space group Triclinic, P-1 Unit cell dimensions a = 13.2771(2) A alpha = 114.559(8) deg. b = 13.3199(2) A beta = 95.207(7) deg. c = 15.2657(10) A gamma = 90.164(6) deg. Volume 2442.91(17) A^3 Z, Calculated density 2, 1.352 Mg/m^3 Absorption coefficient 0.904 mm^-1 F(000) 1014 Crystal size 0.25 x 0.20 x 0.20 mm Theta range for data collection 3.00 to 27.6 deg.
85
Limiting indices -17<=h<=17, -17<=k<=17, -19<=l<=19 Reflections collected / unique 82535 / 11207 [R(int) = 0.0635] Completeness to theta = 27.48 99.8 % Absorption correction Semi-empirical from equivalents Max. and min. transmission 1.000 and 0.836 Refinement method Full-matrix least-squares on F^2 Data / restraints / parameters 11207 / 71 / 659 Goodness-of-fit on F^2 1.036 Final R indices [I>2sigma(I)] R1 = 0.0451, wR2 = 0.1128 R indices (all data) R1 = 0.0560, wR2 = 0.1179 Largest diff. peak and hole 1.356 and -0.723 e.A^-3
Atomic coordinates ( x 10^4) and equivalent isotropic displacement parameters (A^2 x 10^3)
U(eq) is defined as one third of the trace of the orthogonalized Uij tensor.
x y z U(eq) x y z U(eq) ______________________________________________________________________________
Sn(1) 2278(1) 1453(1) 2824(1) 23(1) Cl(1) 2457(1) 2326(1) 4633(1) 32(1) N(1) 2655(2) 3064(2) 2962(2) 29(1) N(2) 745(2) 1873(2) 2956(2) 25(1) N(3) 1927(2) -20(2) 2969(2) 24(1) N(4) 3839(2) 1166(2) 2975(2) 26(1) C(1) 3619(2) 3490(3) 3034(2) 29(1) C(2) 3543(2) 4604(3) 3112(3) 33(1) C(3) 2541(2) 4837(3) 3114(3) 35(1) C(4) 1976(2) 3862(2) 3028(2) 28(1) C(5) 928(2) 3774(2) 3059(2) 27(1) C(6) 361(2) 2862(2) 3033(2) 26(1) C(7) -707(2) 2824(3) 3127(3) 32(1) C(8) -949(2) 1819(3) 3116(3) 30(1) C(9) -24(2) 1225(2) 3028(2) 25(1) C(10) 77(2) 187(2) 3055(2) 26(1) C(11) 978(2) -374(2) 3031(2) 25(1) C(12) 1071(2) -1415(3) 3121(3) 31(1) C(13) 2070(2) -1640(3) 3136(3) 31(1)
C(14) 2618(2) -748(2) 3051(2) 26(1) C(15) 3675(2) -629(2) 3083(2) 28(1) C(16) 4234(2) 255(2) 3056(2) 27(1) C(17) 5322(2) 388(3) 3157(3) 35(1) C(18) 5556(2) 1390(3) 3159(3) 35(1) C(19) 4620(2) 1888(3) 3058(2) 28(1) C(20) 4522(2) 2950(3) 3072(2) 28(1) C(21) 356(2) 4793(2) 3199(2) 28(1) C(22) 350(3) 5630(3) 4123(3) 37(1) C(23) -171(3) 6583(3) 4274(3) 41(1) C(24) -683(2) 6706(3) 3499(3) 36(1) C(25) -672(3) 5891(3) 2587(3) 43(1) C(26) -163(3) 4928(3) 2425(3) 37(1) C(27) -859(2) -334(2) 3198(2) 27(1) C(28) -1426(3) -1171(3) 2435(3) 36(1) C(29) -2298(3) -1625(3) 2599(3) 41(1) C(30) -2596(2) -1269(3) 3512(3) 38(1) C(31) -2035(3) -447(3) 4282(3) 40(1) C(32) -1174(3) 25(3) 4121(3) 36(1)
C(33) 4273(2) -1528(3) 3207(3) 30(1)C(34) 4487(3) -1489(3) 4135(3) 39(1) C(35) 5040(3) -2312(3) 4263(3) 44(1) C(36) 5377(3) -3162(3) 3488(3) 44(1) C(37) 5164(3) -3205(3) 2576(3) 49(1) C(38) 4612(3) -2388(3) 2428(3) 42(1) C(39) 5492(2) 3610(2) 3217(3) 28(1) C(40) 5892(3) 3693(3) 2441(3) 39(1) C(41) 6802(3) 4311(3) 2604(3) 46(1) C(42) 7285(3) 4842(3) 3514(3) 41(1) C(43) 6886(3) 4766(3) 4281(3) 43(1) C(44) 5994(3) 4147(3) 4135(3) 38(1)
C(45) 2085(3) 774(4) 1283(3) 51(1) Fe(1A) 2006(1) -671(1) 178(1) 45(1) C(46A) 1252(6) 703(7) 675(7) 43(2) C(47A) 1556(9) 495(8) -302(9) 49(2) C(48A) 2629(7) 574(6) -146(6) 49(2) C(49A) 2950(6) 718(8) 710(7) 62(2) C(50A) 2140(10) -2161(8) -935(6) 83(3) C(51A) 1156(10) -2079( -633(8) 86(3) C(52A) 1233(13) -1883(8) 355(8) 105(4) C(53A) 2274(13) -1874(8) 665(7) 111(5) C(54A) 2803(11) -2046( -134(8) 99(4)
86
Fe(1B) 2799(1) 24(2) 105(1) 79(1) C(46B) 1655(10) 1070(10) 605(7) 76(4) C(47B) 1341(9) 270(10) -266(8) 65(3) C(48B) 1461(14) -744(11) -268(10) 109(5) C(49B) 1808(14 -481(10) 712(10) 107(6) C(50B) 3590(17) -920(15) -995(11) 155(8) C(51B) 3925(18 -1109(18) 166(12)184(10) C(52B) 4260(15) -33(19) 527(15)175(8)
C(53B) 4187(15) 860(20) 228(14)182(10) C(54B) 3805(17) 243(16) -760(13) 167(8) C(55) 530(20) -2980(20) 480(20) 222(12) C(56)1530(20) -3690(20) 340(20) 227(13) C(57) 1722(16) -4730(18) 524(18) 172(9) C(58) 2759(15) -5095(16) 250(17)161(8) C(59) 2730(13) -6212(15) 355(15) 148(7) C(60) 3831(13) -6438(17) 201(15) 150(7)
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Bond lengths [A] and angles [deg] ______________________________________________________________________________ Sn(1)-N(4) 2.117(2) Sn(1)-N(2) 2.119(2) Sn(1)-N(3) 2.119(2) Sn(1)-N(1) 2.121(2) Sn(1)-C(45) 2.130(4) Sn(1)-Cl(1) 2.4981(9) N(1)-C(4) 1.373(4) N(1)-C(1) 1.376(4) N(2)-C(9) 1.375(4) N(2)-C(6) 1.376(4) N(3)-C(11) 1.369(4) N(3)-C(14) 1.372(4) N(4)-C(16) 1.371(4) N(4)-C(19) 1.373(4) C(1)-C(20) 1.408(4) C(1)-C(2) 1.444(4) C(2)-C(3) 1.366(4) C(3)-C(4) 1.450(4) C(4)-C(5) 1.403(4) C(5)-C(6) 1.411(4) C(5)-C(21) 1.503(4) C(6)-C(7) 1.442(4) C(7)-C(8) 1.369(4) C(8)-C(9) 1.449(4) C(9)-C(10) 1.408(4) C(10)-C(11) 1.407(4) C(10)-C(27) 1.499(4) C(11)-C(12) 1.453(4) C(12)-C(13) 1.361(4) C(13)-C(14) 1.449(4) C(14)-C(15) 1.407(4) C(15)-C(16) 1.408(4) C(15)-C(33) 1.505(4) C(16)-C(17) 1.441(4) C(17)-C(18) 1.367(5) C(18)-C(19) 1.438(4) C(19)-C(20) 1.412(4) C(20)-C(39) 1.504(4) C(21)-C(22) 1.389(5) C(21)-C(26) 1.389(5)
C(22)-C(23) 1.391(5) C(23)-C(24) 1.379(5) C(24)-C(25) 1.366(6) C(25)-C(26) 1.392(5) C(27)-C(28) 1.387(5) C(27)-C(32) 1.391(5) C(28)-C(29) 1.395(5) C(29)-C(30) 1.369(6) C(30)-C(31) 1.380(5) C(31)-C(32) 1.392(5) C(33)-C(38) 1.378(5) C(33)-C(34) 1.398(5) C(34)-C(35) 1.391(5) C(35)-C(36) 1.367(6) C(36)-C(37) 1.372(6) C(37)-C(38) 1.397(5) C(39)-C(44) 1.383(5) C(39)-C(40) 1.386(5) C(40)-C(41) 1.403(5) C(41)-C(42) 1.363(6) C(42)-C(43) 1.368(6) C(43)-C(44) 1.387(5) C(45)-C(46B) 1.337(10) C(45)-C(46A) 1.354(9) C(45)-C(49A) 1.489(8) C(45)-C(49B) 1.554(12) C(45)-Fe(1A) 1.956(5) C(45)-Fe(1B) 1.988(4) Fe(1A)-C(46A) 1.980(9) Fe(1A)-C(54A) 2.019(10) Fe(1A)-C(50A) 2.028(9) Fe(1A)-C(51A) 2.031(10) Fe(1A)-C(52A) 2.033(12) Fe(1A)-C(47A) 2.044(9) Fe(1A)-C(53A) 2.047(10) Fe(1A)-C(49A) 2.051(9) Fe(1A)-C(48A) 2.105(7) C(46A)-C(47A) 1.493(12) C(47A)-C(48A) 1.419(13) C(48A)-C(49A) 1.273(12)
87
C(50A)-C(54A) 1.393(12) C(50A)-C(51A) 1.414(14) C(51A)-C(52A) 1.413(13) C(52A)-C(53A) 1.417(15) C(53A)-C(54A) 1.399(14) Fe(1B)-C(49B) 1.943(17) Fe(1B)-C(48B) 1.961(17) Fe(1B)-C(52B) 2.00(2) Fe(1B)-C(50B) 2.019(13) Fe(1B)-C(47B) 2.033(13) Fe(1B)-C(46B) 2.042(11) Fe(1B)-C(54B) 2.061(15) Fe(1B)-C(51B) 2.072(17) Fe(1B)-C(53B) 2.105(18) C(46B)-C(47B) 1.341(13) C(47B)-C(48B) 1.359(14) C(48B)-C(49B) 1.419(14) C(50B)-C(51B) 1.423(15) C(50B)-C(54B) 1.458(16) C(51B)-C(52B) 1.422(18) C(52B)-C(53B) 1.445(17) C(53B)-C(54B) 1.427(17) C(55)-C(56) 1.608(17) C(56)-C(57) 1.539(17) C(57)-C(58) 1.499(16) C(58)-C(59) 1.561(16) C(59)-C(60) 1.513(16) N(4)-Sn(1)-N(2) 169.42(10) N(4)-Sn(1)-N(3) 89.58(9) N(2)-Sn(1)-N(3) 89.39(9) N(4)-Sn(1)-N(1) 89.60(9) N(2)-Sn(1)-N(1) 89.49(9) N(3)-Sn(1)-N(1) 169.39(10) N(4)-Sn(1)-C(45) 97.14(13) N(2)-Sn(1)-C(45) 93.44(13) N(3)-Sn(1)-C(45) 97.12(14) N(1)-Sn(1)-C(45) 93.47(15) N(4)-Sn(1)-Cl(1) 84.81(7) N(2)-Sn(1)-Cl(1) 84.61(7) N(3)-Sn(1)-Cl(1) 84.81(7) N(1)-Sn(1)-Cl(1) 84.58(8) C(45)-Sn(1)-Cl(1) 177.25(11) C(4)-N(1)-C(1) 109.0(2) C(4)-N(1)-Sn(1) 125.4(2) C(1)-N(1)-Sn(1) 125.5(2) C(9)-N(2)-C(6) 108.6(2) C(9)-N(2)-Sn(1) 125.68(19) C(6)-N(2)-Sn(1) 125.6(2) C(11)-N(3)-C(14) 109.3(2) C(11)-N(3)-Sn(1) 125.31(19) C(14)-N(3)-Sn(1) 125.40(19) C(16)-N(4)-C(19) 108.8(2) C(16)-N(4)-Sn(1) 125.5(2) C(19)-N(4)-Sn(1) 125.5(2) N(1)-C(1)-C(20) 125.8(3) N(1)-C(1)-C(2) 108.0(3)
C(20)-C(1)-C(2) 126.1(3) C(3)-C(2)-C(1) 107.6(3) C(2)-C(3)-C(4) 107.4(3) N(1)-C(4)-C(5) 126.2(3) N(1)-C(4)-C(3) 107.9(3) C(5)-C(4)-C(3) 125.8(3) C(4)-C(5)-C(6) 127.4(3) C(4)-C(5)-C(21) 116.1(3) C(6)-C(5)-C(21) 116.4(3) N(2)-C(6)-C(5) 125.7(3) N(2)-C(6)-C(7) 108.3(3) C(5)-C(6)-C(7) 126.0(3) C(8)-C(7)-C(6) 107.6(3) C(7)-C(8)-C(9) 107.2(3) N(2)-C(9)-C(10) 126.0(3) N(2)-C(9)-C(8) 108.2(2) C(10)-C(9)-C(8) 125.8(3) C(11)-C(10)-C(9) 126.8(3) C(11)-C(10)-C(27) 116.7(3) C(9)-C(10)-C(27) 116.4(3) N(3)-C(11)-C(10) 126.7(3) N(3)-C(11)-C(12) 107.6(2) C(10)-C(11)-C(12) 125.6(3) C(13)-C(12)-C(11) 107.7(3) C(12)-C(13)-C(14) 107.4(3) N(3)-C(14)-C(15) 126.0(3) N(3)-C(14)-C(13) 108.0(3) C(15)-C(14)-C(13) 125.9(3) C(14)-C(15)-C(16) 127.4(3) C(14)-C(15)-C(33) 115.8(3) C(16)-C(15)-C(33) 116.7(3) N(4)-C(16)-C(15) 125.9(3) N(4)-C(16)-C(17) 108.0(3) C(15)-C(16)-C(17) 126.0(3) C(18)-C(17)-C(16) 107.4(3) C(17)-C(18)-C(19) 107.5(3) N(4)-C(19)-C(20) 126.0(3) N(4)-C(19)-C(18) 108.1(3) C(20)-C(19)-C(18) 125.8(3) C(1)-C(20)-C(19) 127.3(3) C(1)-C(20)-C(39) 116.4(3) C(19)-C(20)-C(39) 116.2(3) C(22)-C(21)-C(26) 118.8(3) C(22)-C(21)-C(5) 119.4(3) C(26)-C(21)-C(5) 121.8(3) C(21)-C(22)-C(23) 120.7(3) C(24)-C(23)-C(22) 119.9(4) C(25)-C(24)-C(23) 119.7(3) C(24)-C(25)-C(26) 121.1(4) C(21)-C(26)-C(25) 119.8(4) C(28)-C(27)-C(32) 118.6(3) C(28)-C(27)-C(10) 121.9(3) C(32)-C(27)-C(10) 119.5(3) C(27)-C(28)-C(29) 120.0(3) C(30)-C(29)-C(28) 120.8(3) C(29)-C(30)-C(31) 120.1(3)
88
C(30)-C(31)-C(32) 119.5(3) C(27)-C(32)-C(31) 121.1(3) C(38)-C(33)-C(34) 119.3(3) C(38)-C(33)-C(15) 121.5(3) C(34)-C(33)-C(15) 119.2(3) C(35)-C(34)-C(33) 119.9(4) C(36)-C(35)-C(34) 120.6(4) C(35)-C(36)-C(37) 119.6(3) C(36)-C(37)-C(38) 121.0(4) C(33)-C(38)-C(37) 119.6(4) C(44)-C(39)-C(40) 119.3(3) C(44)-C(39)-C(20) 120.0(3) C(40)-C(39)-C(20) 120.8(3) C(39)-C(40)-C(41) 119.1(4) C(42)-C(41)-C(40) 121.0(4) C(41)-C(42)-C(43) 119.8(3) C(42)-C(43)-C(44) 120.2(4) C(39)-C(44)-C(43) 120.6(4) C(46B)-C(45)-C(46A) 33.1(6) C(46B)-C(45)-C(49A) 78.6(7) C(46A)-C(45)-C(49A) 104.5(6) C(46B)-C(45)-C(49B) 95.7(8) C(49A)-C(45)-Sn(1) 121.5(5) C(49B)-C(45)-Sn(1) 118.8(6) Fe(1A)-C(45)-Sn(1) 139.2(2) Fe(1B)-C(45)-Sn(1) 143.4(2) C(45)-Fe(1A)-C(46A) 40.2(3) C(45)-Fe(1A)-C(54A) 133.4(3) C(46A)-Fe(1A)-C(54A) 172.0(4) C(45)-Fe(1A)-C(50A) 171.9(4) C(46A)-Fe(1A)-C(50A) 146.6(4 C(54A)-Fe(1A)-C(50A) 40.3(4) C(45)-Fe(1A)-C(51A) 146.6(4) C(46A)-Fe(1A)-C(51A) 115.7(4) C(54A)-Fe(1A)-C(51A) 67.3(5) C(50A)-Fe(1A)-C(51A) 40.8(4) C(45)-Fe(1A)-C(52A) 115.0(3) C(46A)-Fe(1A)-C(52A) 109.2(5
C(54A)-Fe(1A)-C(52A) 67.7(6) C(50A)-Fe(1A)-C(52A) 69.0(5) C(51A)-Fe(1A)-C(52A) 40.7(4) C(46A)-Fe(1A)-C(47A) 43.5(3) C(54A)-Fe(1A)-C(47A) 144.0(5 C(50A)-Fe(1A)-C(47A) 111.7(4 C(51A)-Fe(1A)-C(47A) 107.4(5 C(52A)-Fe(1A)-C(47A) 132.5(6) C(45)-Fe(1A)-C(53A) 109.3(3) C(46A)-Fe(1A)-C(53A) 132.7(4 C(54A)-Fe(1A)-C(53A) 40.3(4) C(50A)-Fe(1A)-C(53A) 68.7(4) C(51A)-Fe(1A)-C(53A) 68.1(5) C(52A)-Fe(1A)-C(53A) 40.7(4) C(47A)-Fe(1A)-C(53A) 173.0(6 C(45)-Fe(1A)-C(49A) 43.6(3) C(46A)-Fe(1A)-C(49A) 67.8(3) C(54A)-Fe(1A)-C(49A) 111.0(5 C(50A)-Fe(1A)-C(49A) 129.9(5) C(51A)-Fe(1A)-C(49A) 167.5(4 C(52A)-Fe(1A)-C(49A) 151.4(5) C(47A)-Fe(1A)-C(49A) 66.2(5) C(53A)-Fe(1A)-C(49A) 119.3(5) C(45)-Fe(1A)-C(48A) 67.9(3) C(46A)-Fe(1A)-C(48A) 67.7(3) C(54A)-Fe(1A)-C(48A) 116.4(5) C(50A)-Fe(1A)-C(48A) 109.1(4) C(51A)-Fe(1A)-C(48A) 132.9(4 C(52A)-Fe(1A)-C(48A) 171.8(5) C(47A)-Fe(1A)-C(48A) 40.0(3) C(53A)-Fe(1A)-C(48A) 146.9(5 C(49A)-Fe(1A)-C(48A) 35.6(3) C(45)-C(46A)-C(47A) 109.8(8) C(45)-C(46A)-Fe(1A) 69.0(4) C(47A)-C(46A)-Fe(1A) 70.5(5) C(46B)-C(45)-Fe(1A) 81.3(5) C(46A)-C(45)-Fe(1A) 70.8(4) C(49A)-C(45)-C(49B) 92.5(8)
C(46A)-C(45)-C(49B) 74.3(7) C(49A)-C(45)-Fe(1A) 71.6(4) C(49B)-C(45)-Fe(1A) 23.5(6) C(46B)-C(45)-Fe(1B) 72.8(5) C(45)-Fe(1A)-C(47A) 71.2(4) C(46A)-C(45)-Fe(1B) 86.6(5) C(49A)-C(45)-Fe(1B) 29.3(4) C(49B)-C(45)-Fe(1B) 65.2(7) Fe(1A)-C(45)-Fe(1B) 42.85(11 C(46B)-C(45)-Sn(1) 136.7(5)
C(46A)-C(45)-Sn(1) 129.9(5) C(48A)-C(47A)-C(46A) 102.8(9)
C(48A)-C(47A)-Fe(1A) 72.3(5) C(46A)-C(47A)-Fe(1A) 65.9(5) C(49A)-C(48A)-C(47A) 112.2(8) C(49A)-C(48A)-Fe(1A) 69.8(5) C(47A)-C(48A)-Fe(1A) 67.7(4) C(48A)-C(49A)-C(45) 110.4(7)
C(48A)-C(49A)-Fe(1A) 74.5(5) C(45)-C(49A)-Fe(1A) 64.9(4) C(54A)-C(50A)-C(51A) 106.1(11) C(54A)-C(50A)-Fe(1A) 69.5(5) C(51A)-C(50A)-Fe(1A) 69.8(5) C(52A)-C(51A)-C(50A) 108.9(12) C(52A)-C(51A)-Fe(1A) 69.7(6) C(50A)-C(51A)-Fe(1A) 69.5(6) C(51A)-C(52A)-C(53A) 107.5(12) C(51A)-C(52A)-Fe(1A) 69.6(6) C(53A)-C(52A)-Fe(1A) 70.2(7) C(54A)-C(53A)-C(52A) 106.6(10) C(54A)-C(53A)-Fe(1A) 68.8(6) C(52A)-C(53A)-Fe(1A) 69.2(6) C(50A)-C(54A)-C(53A) 110.8(12) C(50A)-C(54A)-Fe(1A) 70.2(6) C(53A)-C(54A)-Fe(1A) 70.9(6) C(49B)-Fe(1B)-C(48B) 42.6(5)
89
C(49B)-Fe(1B)-C(45) 46.6(4) C(48B)-Fe(1B)-C(45) 76.9(5) C(49B)-Fe(1B)-C(52B) 117.2(8) C(48B)-Fe(1B)-C(52B) 146.5(9) C(45)-Fe(1B)-C(52B) 108.0(5) C(49B)-Fe(1B)-C(50B) 127.2(7) C(48B)-Fe(1B)-C(50B) 102.5(8) C(45)-Fe(1B)-C(50B) 170.3(5) C(52B)-Fe(1B)-C(50B) 67.0(8) C(49B)-Fe(1B)-C(47B) 66.0(5) C(48B)-Fe(1B)-C(47B) 39.7(4) C(45)-Fe(1B)-C(47B) 69.6(3) C(52B)-Fe(1B)-C(47B) 173.5(8) C(50B)-Fe(1B)-C(47B) 116.2(7) C(49B)-Fe(1B)-C(46B) 65.2(5) C(48B)-Fe(1B)-C(46B) 67.4(6) C(45)-Fe(1B)-C(46B) 38.7(3) C(52B)-Fe(1B)-C(46B) 136.5(7) C(50B)-Fe(1B)-C(46B) 150.1(6) C(47B)-Fe(1B)-C(46B) 38.4(4) C(49B)-Fe(1B)-C(54B) 168.4(6) C(48B)-Fe(1B)-C(54B) 129.1(7) C(45)-Fe(1B)-C(54B) 144.9(6) C(52B)-Fe(1B)-C(54B) 64.8(9) C(50B)-Fe(1B)-C(54B) 41.8(5) C(47B)-Fe(1B)-C(54B) 113.3(7) C(46B)-Fe(1B)-C(54B) 122.1(7) C(49B)-Fe(1B)-C(51B) 105.1(8) C(48B)-Fe(1B)-C(51B) 110.2(9) C(45)-Fe(1B)-C(51B) 130.2(5) C(52B)-Fe(1B)-C(51B) 40.8(6) C(50B)-Fe(1B)-C(51B) 40.7(5) C(47B)-Fe(1B)-C(51B) 145.2(8) C(46B)-Fe(1B)-C(51B) 168.5(6) C(54B)-Fe(1B)-C(51B) 68.6(9) C(49B)-Fe(1B)-C(53B) 148.9(7) C(48B)-Fe(1B)-C(53B) 168.3(7) C(45)-Fe(1B)-C(53B) 110.9(6)
C(52B)-Fe(1B)-C(53B) 41.1(5) C(50B)-Fe(1B)-C(53B) 71.3(9) C(47B)-Fe(1B)-C(53B) 133.3(8) C(46B)-Fe(1B)-C(53B) 112.8(8) C(54B)-Fe(1B)-C(53B) 40.0(5) C(51B)-Fe(1B)-C(53B) 72.0(9) C(45)-C(46B)-C(47B) 118.1(10) C(45)-C(46B)-Fe(1B) 68.5(5) C(47B)-C(46B)-Fe(1B) 70.4(7) C(46B)-C(47B)-C(48B) 110.8(11) C(46B)-C(47B)-Fe(1B) 71.2(7) C(48B)-C(47B)-Fe(1B) 67.3(9) C(47B)-C(48B)-C(49B) 102.5(11) C(47B)-C(48B)-Fe(1B) 73.0(8) C(49B)-C(48B)-Fe(1B) 68.0(9) C(48B)-C(49B)-C(45) 111.4(10) C(48B)-C(49B)-Fe(1B) 69.4(9) C(45)-C(49B)-Fe(1B) 68.2(6) C(51B)-C(50B)-C(54B) 107.8(18) C(51B)-C(50B)-Fe(1B) 71.6(9) C(54B)-C(50B)-Fe(1B) 70.6(8) C(52B)-C(51B)-C(50B) 102.5(19) C(52B)-C(51B)-Fe(1B) 66.9(11) C(50B)-C(51B)-Fe(1B) 67.7(8) C(51B)-C(52B)-C(53B) 118(2) C(51B)-C(52B)-Fe(1B) 72.3(11) C(53B)-C(52B)-Fe(1B) 73.3(12) C(54B)-C(53B)-C(52B) 99(2) C(54B)-C(53B)-Fe(1B) 68.3(9) C(52B)-C(53B)-Fe(1B) 65.6(12) C(53B)-C(54B)-C(50B) 113.0(19) C(53B)-C(54B)-Fe(1B) 71.6(9) C(50B)-C(54B)-Fe(1B) 67.5(8) C(57)-C(56)-C(55) 129(2) C(58)-C(57)-C(56) 107.8(19) C(57)-C(58)-C(59) 98.9(14) C(60)-C(59)-C(58) 95.2(1)
Anisotropic displacement parameters (A^2 x 10^3)
The anisotropic displacement factor exponent takes the form:
-2 pi^2 [ h^2 a*^2 U11 + ... + 2 h k a* b* U12 ]
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U11 U22 U33 U23 U13 U12 _______________________________________________________________________
Sn(1) 18(1) 20(1) 35(1) 15(1) 5(1) 3(1) Cl(1) 31(1) 30(1) 37(1) 14(1) 5(1) 3(1) N(1) 20(1) 26(1) 49(2) 23(1) 9(1) 4(1)
90
N(2) 23(1) 21(1) 36(1) 15(1) 4(1) 2(1) N(3) 18(1) 21(1) 36(1) 14(1) 4(1) 1(1) N(4) 22(1) 22(1) 38(2) 16(1) 7(1) 4(1) C(1) 26(2) 25(2) 43(2) 21(1) 8(1) 2(1) C(2) 28(2) 24(2) 55(2) 24(2) 8(1) 3(1) C(3) 26(2) 29(2) 59(2) 27(2) 7(2) 1(1) C(4) 24(2) 23(1) 42(2) 18(1) 6(1) 4(1) C(5) 23(1) 22(1) 40(2) 18(1) 4(1) 4(1) C(6) 23(1) 24(1) 35(2) 16(1) 3(1) 5(1) C(7) 23(2) 31(2) 51(2) 24(2) 7(1) 5(1) C(8) 21(1) 28(2) 47(2) 20(2) 4(1) 4(1) C(9) 19(1) 24(1) 35(2) 15(1) 2(1) 0(1) C(10) 20(1) 23(1) 34(2) 13(1) 1(1) 0(1) C(11) 22(1) 22(1) 35(2) 14(1) 3(1) 1(1) C(12) 26(2) 25(2) 49(2) 22(2) 4(1) 0(1) C(13) 26(2) 24(2) 50(2) 20(2) 4(1) 1(1) C(14) 23(1) 21(1) 36(2) 14(1) 5(1) 3(1) C(15) 22(1) 23(1) 41(2) 15(1) 5(1) 5(1) C(16) 23(1) 22(1) 41(2) 17(1) 6(1) 5(1) C(17) 21(2) 33(2) 60(2) 27(2) 8(1) 6(1) C(18) 21(2) 30(2) 60(2) 24(2) 9(1) 6(1) C(19) 18(1) 27(2) 43(2) 19(1) 7(1) 2(1) C(20) 21(1) 25(2) 41(2) 17(1) 6(1) 1(1) C(21) 20(1) 24(2) 46(2) 20(1) 7(1) 2(1) C(22) 36(2) 35(2) 44(2) 20(2) 5(2) 9(1) C(23) 33(2) 30(2) 56(2) 14(2) 12(2) 8(1) C(24) 24(2) 28(2) 67(2) 30(2) 12(2) 6(1) C(25) 38(2) 43(2) 60(2) 35(2) 2(2) 11(2) C(26) 36(2) 34(2) 45(2) 19(2) 2(2) 9(1) C(27) 19(1) 24(1) 43(2) 19(1) 3(1) 2(1) C(28) 34(2) 36(2) 42(2) 19(2) 1(1) -7(1) C(29) 29(2) 41(2) 57(2) 26(2) -8(2) -12(2) C(30) 20(2) 36(2) 72(3) 37(2) 7(2) 3(1) C(31) 35(2) 38(2) 56(2) 24(2) 20(2) 5(2) C(32) 32(2) 32(2) 43(2) 13(2) 8(1) -1(1) C(33) 18(1) 24(2) 53(2) 22(2) 6(1) 3(1) C(34) 31(2) 38(2) 53(2) 25(2) 6(2) 9(1) C(35) 32(2) 49(2) 69(3) 41(2) 4(2) 6(2) C(36) 23(2) 31(2) 89(3) 37(2) 4(2) 3(1) C(37) 41(2) 28(2) 74(3) 15(2) 8(2) 11(2) C(38) 40(2) 33(2) 54(2) 18(2) 3(2) 12(2) C(39) 20(1) 21(1) 47(2) 17(1) 9(1) 4(1) C(40) 36(2) 37(2) 49(2) 20(2) 14(2) -0(2) C(41) 39(2) 42(2) 69(3) 30(2) 28(2) 6(2) C(42) 22(2) 28(2) 79(3) 28(2) 9(2) 3(1) C(43) 32(2) 35(2) 61(2) 22(2) -4(2) -4(1) C(44) 33(2) 38(2) 49(2) 23(2) 5(2) -3(1) C(45) 49(2) 67(3) 39(2) 23(2) 10(2) 25(2) Fe(1A) 61(1) 39(1) 31(1) 10(1) 2(1) 12(1) C(46A) 36(4) 48(5) 50(5) 27(4) -2(3) -1(3) C(47A) 80(4) 39(3) 58(3) 42(3) 40(3) 19(3) C(48A) 80(4) 39(3) 58(3) 42(3) 40(3) 19(3) C(49A) 40(4) 61(6) 61(5) -1(5) 19(4) -12(4) C(50A) 135(9) 60(6) 32(4) -1(4) 0(5) 48(7) C(51A) 132(8) 37(5) 66(6) 2(5) -10(6) -7(6) C(52A) 202(11) 30(5) 73(6) 6(5) 36(7) -13(7)
91
C(53A) 244(14) 32(5) 38(5) 3(4) -16(6) 38(8) C(54A) 146(9) 58(6) 70(7) 11(6) -14(6) 54(7) Fe(1B) 89(1) 93(2) 48(1) 18(1) 26(1) 28(1) C(46B) 120(12) 66(6) 48(6) 30(5) 9(6) 41(7) C(47B) 69(7) 102(8) 42(5) 51(5) -7(5) -29(6) C(48B) 162(15) 80(7) 70(7) 25(6) -33(10) -34(9) C(49B) 210(19) 61(6) 49(7) 23(6) 14(9) 12(9) C(50B) 260(20) 142(11) 76(7) 44(8) 88(10) 117(13) C(51B) 260(30) 194(15) 96(11) 52(11) 59(14) 159(17) C(52B) 130(16) 260(20) 103(10) 37(11) 68(9) 69(16) C(53B) 140(18) 245(17) 148(14) 54(12) 87(14) -42(15) C(54B) 230(20) 163(13) 115(10) 46(10) 130(13) 42(15)
CIF Information for Compound 3:
Crystal data and structure refinement Empirical formula C64 H46 Fe2 N4 Sn1 Formula weight 1101.48 Temperature 173 K Wavelength 0.71073 A Crystal system, space group Triclinic, P -1 Unit cell dimensions a = 10.7368(10) A alpha = 101.6570(10) deg. b = 11.2881(10) A beta = 108.0820(10) deg. c = 12.1733(11) A gamma = 115.0580(10) deg. Volume 1171.36(19) A^3 Z, Calculated density 1, 1.561 Mg/m^3 Absorption coefficient 1.189 mm^-1 F(000) 560 Crystal size 0.110 x 0.050 x 0.030 mm Theta range for data collection 1.909 to 29.129 deg. Limiting indices -14<=h<=14, -15<=k<=15, -16<=l<=16 Reflections collected / unique 16707 / 6273 [R(int) = 0.034] Completeness to theta = 28.255 99.5 % Absorption correction None Max. and min. transmission 0.9649 and 0.9423 Refinement method Full-matrix least-squares on F^2 Data / restraints / parameters 6252 / 0 / 322 Goodness-of-fit on F^2 0.9889 Final R indices [I>2sigma(I)] R1 = 0.0354, wR2 = 0.0901 R indices (all data) R1 = 0.0485, wR2 = 0.1059 Largest diff. peak and hole 1.41 and -1.46 e.A^-3 Atomic coordinates ( x 10^4) and equivalent isotropic displacement parameters (A^2 x 10^3)
U(eq) is defined as one third of the trace of the orthogonalized Uij tensor.
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92
x y z U(eq) x y z U(eq) ______________________________________________________________________________
C(6) 3175(3) 1829(3) 7358(2) 14 C(5) 3550(3) 3031(3) 7035(3) 15 C(4) 2624(3) 3163(3) 6008(3) 14 C(1) 640(3) 2633(3) 4273(2) 14 C(2) 1849(3) 4089(3) 4644(3) 16 C(3) 3065(3) 4407(3) 5704(3) 17 C(10) 803(3) -1848(3) 6802(2) 12 C(9) 1934(3) -386(3) 7252(2) 13 C(17)1192(3) -2658(3) 7541(3) 13 C(18 1546(3) -2235(3) 8813(3) 16 C(19 1884(3) -3012(3) 9482(3) 20 C(20)1845(3) -4224(3) 8890(3) 22 C(21 1500(4) -4647(3) 7633(3) 22 C(22 1198(4) -3859(3) 6965(3) 19 C(8) 3460(3) 346(3) 8278(3) 16 C(7) 4211(3) 1702(3) 8352(3) 16 C(11) 5153(3) 4284(3) 7841(2) 13 C(12) 5453(3) 5477(3) 8743(3) 19
C(13) 6960(3) 6625(3) 9473(3) 21 C(14) 8157(3) 6582(3) 9304(3) 20 C(15) 7870(3) 5406(3) 8406(3) 21 C(16) 6368(3) 4253(3) 7674(3) 20 C(23) 1179(3) -673(3) 4083(3) 15 C(24) 2653(3) -516(3) 4704(3) 21 C(28) 3958(6) 2157(4) 3771(4) 43 C(32) 2500(6) 1677(4) 2788(4) 41 C(31) 2218(5) 659(4) 1705(4) 31 C(30) 3530(4) 524(4) 2011(3 27 C(29) 4594(5) 1450(4) 3271(4 35 C(25) 2857(4) -1400(4) 3853(3) 25 C(26) 1516(4) -2128(3) 2694(3) 25 C(27) 497(4) -1685(3) 2839(3) 21 Fe(1) 2536(1) 12(1) 3172(1) 19 N(2) 1805(3) 563(2) 6749(2) 13 N(1) 1170(3) 2125(2) 5119(2) 13 Sn(1) 0 0 5000 1
Bond lengths [A] and angles [deg]
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C(6)-C(5) 1.417(4) C(6)-C(7) 1.447(3) C(6)-N(2) 1.368(3) C(5)-C(4) 1.416(4) C(5)-C(11) 1.501(3) C(4)-C(3) 1.445(4) C(4)-N(1) 1.367(3) C(1)-C(10)#1 1.417(4) C(1)-C(2) 1.456(4) C(1)-N(1) 1.365(3) C(2)-C(3) 1.366(4) C(10)-C(9) 1.422(4) C(10)-C(17) 1.497(3) C(9)-C(8) 1.447(3) C(9)-N(2) 1.371(3) C(17)-C(18) 1.398(4) C(17)-C(22) 1.399(4) C(18)-C(19) 1.391(4) C(19)-C(20) 1.389(5) C(20)-C(21) 1.382(4) C(21)-C(22) 1.389(4) C(8)-C(7) 1.361(4) C(11)-C(12) 1.392(4)
C(11)-C(16) 1.394(4) C(12)-C(13) 1.398(4) C(13)-C(14) 1.381(4) C(14)-C(15) 1.382(4) C(15)-C(16) 1.397(4) C(23)-C(24) 1.439(4) C(23)-C(27) 1.427(4) C(23)-Fe(1) 2.084(3) C(23)-Sn(1) 2.186(3) C(24)-C(25) 1.424(4) C(24)-Fe(1) 2.054(3) C(28)-C(32) 1.426(7) C(28)-C(29) 1.414(6) C(28)-Fe(1) 2.047(4) C(32)-C(31) 1.413(6) C(32)-Fe(1) 2.040(4) C(31)-C(30) 1.423(5) C(31)-Fe(1) 2.049(4) C(30)-C(29) 1.415(5) C(30)-Fe(1) 2.053(3) C(29)-Fe(1) 2.062(4) C(25)-C(26) 1.416(5) C(25)-Fe(1) 2.041(3)
93
C(26)-C(27) 1.425(4) C(26)-Fe(1) 2.042(3) C(27)-Fe(1) 2.052(3) N(2)-Sn(1) 2.131(2) N(1)-Sn(1) 2.132(2) C(5)-C(6)-C(7) 125.7(2) C(5)-C(6)-N(2) 126.3(2) C(7)-C(6)-N(2) 107.9(2) C(6)-C(5)-C(4) 127.8(2) C(6)-C(5)-C(11) 115.9(2) C(4)-C(5)-C(11) 116.3(2) C(5)-C(4)-C(3) 125.9(2) C(5)-C(4)-N(1) 125.8(2) C(3)-C(4)-N(1) 108.3(2) C(10)#1-C(1)-C(2) 126.7(2) C(10)#1-C(1)-N(1) 125.6(2) C(2)-C(1)-N(1) 107.7(2) C(1)-C(2)-C(3) 107.5(2) C(4)-C(3)-C(2) 107.2(2) C(1)#1-C(10)-C(9) 127.6(2) C(1)#1-C(10)-C(17) 116.2(2) C(9)-C(10)-C(17) 116.2(2) C(10)-C(9)-C(8) 126.0(2) C(10)-C(9)-N(2) 126.2(2) C(8)-C(9)-N(2) 107.8(2) C(10)-C(17)-C(18) 120.8(2) C(10)-C(17)-C(22) 120.4(2) C(18)-C(17)-C(22) 118.8(2) C(17)-C(18)-C(19) 120.1(3) C(18)-C(19)-C(20) 120.5(3) C(19)-C(20)-C(21) 119.8(3) C(20)-C(21)-C(22) 120.1(3) C(17)-C(22)-C(21) 120.7(3) C(9)-C(8)-C(7) 107.5(2) C(6)-C(7)-C(8) 107.5(2) C(5)-C(11)-C(12) 121.7(2) C(5)-C(11)-C(16) 119.0(2) C(12)-C(11)-C(16) 119.3(2) C(11)-C(12)-C(13) 120.0(3) C(12)-C(13)-C(14) 120.2(3) C(13)-C(14)-C(15) 120.2(3) C(14)-C(15)-C(16) 119.9(3) C(15)-C(16)-C(11) 120.3(3) C(24)-C(23)-C(27) 105.3(3) C(24)-C(23)-Fe(1) 68.51(16) C(27)-C(23)-Fe(1) 68.59(16) C(24)-C(23)-Sn(1) 125.9(2) C(27)-C(23)-Sn(1) 126.6(2) Fe(1)-C(23)-Sn(1) 140.10(14) C(23)-C(24)-C(25) 109.5(3) C(23)-C(24)-Fe(1) 70.79(17) C(25)-C(24)-Fe(1) 69.17(19) C(32)-C(28)-C(29) 106.8(4) C(32)-C(28)-Fe(1) 69.3(2) C(29)-C(28)-Fe(1) 70.4(2) C(28)-C(32)-C(31) 109.3(4)
C(28)-C(32)-Fe(1) 69.8(2) C(31)-C(32)-Fe(1) 70.1(2) C(32)-C(31)-C(30) 106.8(4) C(32)-C(31)-Fe(1) 69.4(2) C(30)-C(31)-Fe(1) 69.8(2) C(31)-C(30)-C(29) 108.5(3) C(31)-C(30)-Fe(1) 69.56(19) C(29)-C(30)-Fe(1) 70.23(19) C(30)-C(29)-C(28) 108.5(4) C(30)-C(29)-Fe(1) 69.5(2) C(28)-C(29)-Fe(1) 69.3(2) C(24)-C(25)-C(26) 107.7(3) C(24)-C(25)-Fe(1) 70.14(18) C(26)-C(25)-Fe(1) 69.73(19) C(25)-C(26)-C(27) 107.6(3) C(25)-C(26)-Fe(1) 69.67(18) C(27)-C(26)-Fe(1) 70.01(18) C(23)-C(27)-C(26) 109.9(3) C(23)-C(27)-Fe(1) 71.04(16) C(26)-C(27)-Fe(1) 69.26(18) C(23)-Fe(1)-C(29) 148.57(14) C(23)-Fe(1)-C(24) 40.70(11) C(29)-Fe(1)-C(24) 116.30(15) C(23)-Fe(1)-C(30) 170.42(13) C(29)-Fe(1)-C(30) 40.22(15) C(24)-Fe(1)-C(30) 147.60(13) C(23)-Fe(1)-C(27) 40.37(11) C(29)-Fe(1)-C(27) 169.50(15) C(24)-Fe(1)-C(27) 67.45(12) C(30)-Fe(1)-C(27) 131.59(14) C(23)-Fe(1)-C(31) 131.68(13) C(29)-Fe(1)-C(31) 68.15(16) C(24)-Fe(1)-C(31) 171.04(14) C(30)-Fe(1)-C(31) 40.61(14) C(27)-Fe(1)-C(31) 109.66(15) C(23)-Fe(1)-C(28) 116.71(14) C(29)-Fe(1)-C(28) 40.26(17) C(24)-Fe(1)-C(28) 109.04(15) C(30)-Fe(1)-C(28) 68.12(15) C(27)-Fe(1)-C(28) 149.62(16) C(23)-Fe(1)-C(26) 68.91(12) C(29)-Fe(1)-C(26) 130.02(15) C(24)-Fe(1)-C(26) 68.09(13) C(30)-Fe(1)-C(26) 107.96(14) C(27)-Fe(1)-C(26) 40.73(13) C(23)-Fe(1)-C(25) 69.05(12) C(29)-Fe(1)-C(25) 107.79(16) C(24)-Fe(1)-C(25) 40.69(12) C(30)-Fe(1)-C(25) 114.92(14) C(27)-Fe(1)-C(25) 68.13(13) C(23)-Fe(1)-C(32) 110.06(14) C(29)-Fe(1)-C(32) 67.56(18) C(24)-Fe(1)-C(32) 132.49(15) C(30)-Fe(1)-C(32) 67.61(15) C(27)-Fe(1)-C(32) 117.96(17)
94
C(31)-Fe(1)-C(28) 68.85(17) C(31)-Fe(1)-C(26) 115.73(15) C(28)-Fe(1)-C(26) 168.56(19) C(31)-Fe(1)-C(25) 147.25(14) C(28)-Fe(1)-C(25) 130.14(18) C(26)-Fe(1)-C(25) 40.60(14) C(31)-Fe(1)-C(32) 40.43(16) C(28)-Fe(1)-C(32) 40.8(2) C(26)-Fe(1)-C(32) 148.94(18) C(25)-Fe(1)-C(32) 170.21(18) C(9)-N(2)-C(6) 109.2(2) C(9)-N(2)-Sn(1) 124.51(17) C(6)-N(2)-Sn(1) 124.27(17) C(4)-N(1)-C(1) 109.3(2) C(4)-N(1)-Sn(1) 124.92(18) C(1)-N(1)-Sn(1) 125.56(18) C(23)-Sn(1)-C(23)#1 179.995 C(23)-Sn(1)-N(1)#1 85.90(9) C(23)#1-Sn(1)-N(1)#1 94.10(9) C(23)-Sn(1)-N(1) 94.10(9) C(23)#1-Sn(1)-N(1) 85.90(9) N(1)#1-Sn(1)-N(1) 179.995 C(23)-Sn(1)-N(2)#1 92.22(10) C(23)#1-Sn(1)-N(2)#1 87.78(10) N(1)#1-Sn(1)-N(2)#1 90.08(8) N(1)-Sn(1)-N(2)#1 89.92(8) C(23)-Sn(1)-N(2) 87.78(10) C(23)#1-Sn(1)-N(2) 92.22(10) N(1)#1-Sn(1)-N(2) 89.92(8) N(1)-Sn(1)-N(2) 90.08(8) N(2)#1-Sn(1)-N(2) 179.995
95
Symmetry transformations used to generate equivalent atoms:
#1 -x,-y,-z+1
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Anisotropic displacement parameters (A^2 x 10^3)
The anisotropic displacement factor exponent takes the form:
-2 pi^2 [ h^2 a*^2 U11 + ... + 2 h k a* b* U12 ]
_______________________________________________________________________ U11 U22 U33 U23 U13 U12 _______________________________________________________________________ C(6) 10(1) 14(1) 12(1) 5(1) 2(1) 5(1) C(5) 10(1) 14(1) 15(1) 5(1) 3(1) 3(1) C(4) 11(1) 12(1) 16(1) 6(1) 6(1) 3(1) C(1) 12(1) 13(1) 14(1) 7(1) 5(1) 5(1) C(2) 14(1) 13(1) 18(1) 9(1) 5(1) 4(1) C(3) 17(1) 13(1) 18(1) 8(1) 5(1) 5(1) C(10) 12(1) 14(1) 12(1) 7(1) 5(1) 7(1) C(9) 11(1) 16(1) 13(1) 7(1) 4(1) 8(1) C(17) 11(1) 14(1) 16(1) 8(1) 5(1) 6(1) C(18) 11(1) 18(1) 15(1) 8(1) 5(1) 6(1) C(19) 14(1) 26(1) 17(1) 13(1) 4(1) 8(1) C(20) 18(1) 24(1) 24(1) 16(1) 6(1) 11(1) C(21) 23(1) 18(1) 28(2) 13(1) 10(1) 14(1) C(22) 23(1) 19(1) 17(1) 7(1) 8(1) 13(1) C(8) 11(1) 19(1) 15(1) 9(1) 1(1) 7(1) C(7) 8(1) 17(1) 16(1) 8(1) 1(1) 5(1) C(11) 9(1) 13(1) 12(1) 5(1) 1(1) 3(1) C(12) 15(1) 19(1) 21(1) 6(1) 7(1) 8(1) C(13) 19(1) 16(1) 18(1) 2(1) 4(1) 5(1) C(14) 12(1) 17(1) 19(1) 8(1) 3(1) 1(1) C(15) 13(1) 23(1) 22(1) 7(1) 7(1) 7(1) C(16) 14(1) 16(1) 22(1) 3(1) 5(1) 6(1) C(23) 13(1) 15(1) 17(1) 8(1) 6(1) 6(1) C(24) 17(1) 23(1) 23(1) 10(1) 8(1) 12(1) C(28) 67(3) 17(2) 44(2) 11(2) 40(2) 10(2) C(32) 66(3) 37(2) 57(3) 34(2) 49(2) 36(2) C(31) 41(2) 33(2) 38(2) 24(2) 27(2) 23(2) C(30) 34(2) 30(2) 30(2) 15(1) 23(1) 17(1) C(29) 30(2) 29(2) 38(2) 14(2) 19(2) 4(2) C(25) 27(2) 27(2) 34(2) 15(1) 19(1) 19(1) C(26) 30(2) 18(1) 29(2) 8(1) 19(1) 10(1) C(27) 22(1) 17(1) 22(1) 7(1) 11(1) 7(1) Fe(1) 21(1) 17(1) 22(1) 8(1) 12(1) 9(1) N(2) 9(1) 12(1) 13(1) 6(1) 2(1) 5(1) N(1) 10(1) 12(1) 14(1) 6(1) 4(1) 5(1)
96
Sn(1) 9(1) 10(1) 10(1) 4(1) 2(1) 4(1) _______________________________________________________________________
CIF Information for Compound 4:
Crystal data and structure refinement
Empirical formula C48 H54 Fe N4 O Sn Formula weight 877.49 Temperature 123(2) K Wavelength 0.71069 A Crystal system, space group Triclinic, P-1 Unit cell dimensions a = 10.047(5) A alpha = 73.676(5) deg. b = 14.695(5) A beta = 80.334(5) deg. c = 15.322(5) A gamma = 80.399(5) deg. Volume 2123.0(15) A^3 Z, Calculated density 2, 1.373 Mg/m^3 Absorption coefficient 0.970 mm^-1 F(000) 908 Crystal size 0.22 x 0.20 x 0.18 mm Theta range for data collection 3.07 to 20.79 deg. Limiting indices -10<=h<=10, -14<=k<=14, -15<=l<=15 Reflections collected / unique 26925 / 4395 [R(int) = 0.0271] Completeness to theta = 20.79 99.6 % Absorption correction Semi-empirical from equivalents Max. and min. transmission 0.8448 and 0.8149 Refinement method Full-matrix least-squares on F^2 Data / restraints / parameters 4395 / 80 / 551 Goodness-of-fit on F^2 1.056 Final R indices [I>2sigma(I)] R1 = 0.0401, wR2 = 0.1098 R indices (all data) R1 = 0.0440, wR2 = 0.1125 Largest diff. peak and hole 0.982 and -0.652 e.A^-3
Table 2. Atomic coordinates ( x 10^4) and equivalent isotropic displacement parameters (A^2 x 10^3)
U(eq) is defined as one third of the trace of the orthogonalized Uij tensor.
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97
x y z U(eq) x y z U(eq) ______________________________________________________________________________
Sn(1 1663(1) 2575(1) 2609(1) 56(1) N(1) 574(4) 1421(3) 3324(3) 64(1) N(2) 3341(4) 1598(3) 2295(3) 59(1) N(3) 2887(4) 3687(3) 2095(3) 59(1) N(4) 135(4) 3505(3) 3175(3) 66(1) C(1) -731(5) 1496(4) 3783(4) 64(1) C(2) -1182(6) 557(4) 4064(4) 69(2) C(3) -145(5) -63(4) 3769(3) 65(2) C(4) 971(6) 483(4) 3303(4) 63(1) C(5) 2234(5) 127(4) 2910(4) 65(1) C(6) 3331(5) 631(4) 2453(4) 60(1) C(7) 4614(5) 228(4) 2048(4) 66(1) C(8) 5394(5) 953(4) 1672(4) 65(1) C(9) 4580(5) 1831(4) 1821(3) 59(1) C(10) 4974(5) 2751(4) 1543(4) 61(1) C(11) 4206(5) 3601(4) 1677(3) 61(1) C(12) 4658(6) 4549( 1398(4) 64(1) C(13) 3598(6) 5165(4) 1650(4) 66(1) C(14) 2479(6) 4627(4) 2113(4) 64(1) C(15) 1219(6) 4978(4 2529(4) 68(2) C(16) 155(5) 4463(4) 3041(4) 67(1) C(17) -1105(6) 4851(4) 3489(4) 81(2) C(18) -1860(6) 4112(5) 3878(5) 87(2) C(19) -1069(6) 3252(4) 3676(4) 71(2) C(20) -1466(6) 2338(4) 3940(4) 72(2) C(21) -2562(6) 350(5) 4548(4) 82(2) C(22) -3596(7) 566(6) 3880(5) 108(2) C(23) -116(7) -1108(4) 3851(4) 83(2) C(24) -323(9) -1304(5) 2964(5) 113(2) C(25) 4973(6) -808(4) 2020(5) 84(2)
C(26) 5386(9) -1453(5) 2910(6) 125(3) C(27) 6795(6) 908(4) 1141(4) 79(2) C(28) 6762(7) 1166(5) 115(5) 102(2) C(29) 6063(6) 4755(4) 963(4) 72(2) C(30) 7029(6) 4620(5) 1647(5) 97(2) C(31) 3531(7) 6234(4) 1500(5) 90(2) C(32) 3801(10) 6493(6) 2315(7) 142(3) C(33) -1472(8) 5885(5) 3531(6) 109(2) C(34) -897(14) 6078(7) 4283(8) 198(6) C(35) -3377(11) 4151(6) 4341(6) 153(4) C(36) -3298(11) 3837(9) 5269(9) 185(5) Fe(1) 983(1) 2438(1) 202(1) 69(1) C(37) 683(5) 2901(3) 1387(3) 56(1) C(38) -450(5) 2492(4) 1289(4) 73(2) C(39) -958(6) 3016(5) 455(4) 84(2) C(40) -143(6) 3732(4) 29(4) 80(2) C(41) 858(6) 3661(4) 598(4) 71(2) C(42A) 1120(30) 1910(20) -927(19) 115(9) C(43A) 2170(30) 2477(17) -1024(13) 119(9) C(44A) 2984(18) 2130(20) 300(20) 105(7) C(45A 2400(30) 1300(20) 257(16) 95(8) C(46A)1270(30) 1182(19) -112(19) 129(9) C(42B) 860(30) 1340(30 -370(30) 111(9) C(43B) 1440(40) 2110(30) -990(20) 111(11) C(44B) 2640(30) 2280(20) -730(20) 102(10) C(45B) 2780(30) 1570(30) 120(20) 82(8) C(46B 1730(40) 994(15) 310(20) 103(10) O(1) 2466(4) 2275(3) 3907(3) 79(1) C(47) 3276(11) 2665(10) 4150(5) 194(6) C(48) 3706(9) 2219(6) 4984(5) 123(3)
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Bond lengths [A] and angles [deg]
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Sn(1)-N(3) 2.104(4) Sn(1)-N(1) 2.108(4) Sn(1)-N(2) 2.109(4) Sn(1)-N(4) 2.120(4) Sn(1)-C(37) 2.159(5) Sn(1)-O(1) 2.175(4) N(1)-C(4) 1.377(7) N(1)-C(1) 1.383(7) N(2)-C(6) 1.374(6) N(2)-C(9) 1.376(6) N(3)-C(11) 1.373(6) N(3)-C(14) 1.380(6) N(4)-C(19) 1.367(7) N(4)-C(16) 1.367(7)
C(1)-C(20) 1.392(7) C(1)-C(2) 1.450(7) C(2)-C(3) 1.369(8) C(2)-C(21) 1.495(8) C(3)-C(4) 1.456(7) C(3)-C(23) 1.502(8) C(4)-C(5) 1.395(8) C(5)-C(6) 1.406(7) C(6)-C(7) 1.442(7) C(7)-C(8) 1.365(8) C(7)-C(25) 1.516(8) C(8)-C(9) 1.462(7) C(8)-C(27) 1.504(8) C(9)-C(10) 1.402(7)
98
C(10)-C(11) 1.403(7) C(11)-C(12) 1.463(7) C(12)-C(13) 1.355(8) C(12)-C(29) 1.498(8) C(13)-C(14) 1.451(7) C(13)-C(31) 1.514(8) C(14)-C(15) 1.404(8) C(15)-C(16) 1.409(8) C(16)-C(17) 1.445(8) C(17)-C(18) 1.367(9) C(17)-C(33) 1.520(8) C(18)-C(19) 1.459(8) C(18)-C(35) 1.568(11) C(19)-C(20) 1.395(8) C(21)-C(22) 1.514(9) C(23)-C(24) 1.519(9) C(25)-C(26) 1.503(9) C(27)-C(28) 1.515(9) C(29)-C(30) 1.496(8) C(31)-C(32) 1.481(10) C(33)-C(34) 1.484(12) C(35)-C(36) 1.378(13) Fe(1)-C(43B) 1.98(4) Fe(1)-C(45A) 2.00(2) Fe(1)-C(46A) 2.00(3) Fe(1)-C(39) 2.014(6) Fe(1)-C(40) 2.016(5) Fe(1)-C(38) 2.021(6) Fe(1)-C(44B) 2.03(3) Fe(1)-C(41) 2.032(5) Fe(1)-C(43A) 2.039(19) Fe(1)-C(45B) 2.04(3) Fe(1)-C(44A) 2.054(18) Fe(1)-C(42A) 2.06(2) C(37)-C(41) 1.405(7) C(37)-C(38) 1.421(7) C(38)-C(39) 1.421(8) C(39)-C(40) 1.387(9) C(40)-C(41) 1.412(8) C(42A)-C(46A) 1.408(18) C(42A)-C(43A) 1.409(18) C(43A)-C(44A) 1.414(16) C(44A)-C(45A) 1.423(15) C(45A)-C(46A) 1.411(16) C(42B)-C(43B) 1.39(2) C(42B)-C(46B) 1.41(2) C(43B)-C(44B) 1.41(2) C(44B)-C(45B) 1.43(2) C(45B)-C(46B) 1.40(2) O(1)-C(47) 1.227(11) C(47)-C(48) 1.367(9) N(3)-Sn(1)-N(1) 170.68(15) N(3)-Sn(1)-N(2) 89.40(16) N(1)-Sn(1)-N(2) 89.55(16) N(3)-Sn(1)-N(4) 89.98(17) N(1)-Sn(1)-N(4) 89.23(17)
N(2)-Sn(1)-N(4) 168.59(16) N(3)-Sn(1)-C(37) 94.33(17) N(1)-Sn(1)-C(37) 94.97(18) N(2)-Sn(1)-C(37) 100.56(17) N(4)-Sn(1)-C(37) 90.85(17) N(3)-Sn(1)-O(1) 88.12(15) N(1)-Sn(1)-O(1) 82.56(16) N(2)-Sn(1)-O(1) 84.10(15) N(4)-Sn(1)-O(1) 84.49(16) C(37)-Sn(1)-O(1) 174.74(15) C(4)-N(1)-C(1) 108.6(4) C(4)-N(1)-Sn(1) 125.3(4) C(1)-N(1)-Sn(1) 125.6(3) C(6)-N(2)-C(9) 108.7(4) C(6)-N(2)-Sn(1) 125.3(3) C(9)-N(2)-Sn(1) 125.8(3) C(11)-N(3)-C(14) 109.1(4) C(11)-N(3)-Sn(1) 125.8(3) C(14)-N(3)-Sn(1) 125.1(3) C(19)-N(4)-C(16) 109.4(4) C(19)-N(4)-Sn(1) 125.0(4) C(16)-N(4)-Sn(1) 125.4(4) N(1)-C(1)-C(20) 124.9(5) N(1)-C(1)-C(2) 108.3(5) C(20)-C(1)-C(2) 126.8(5) C(3)-C(2)-C(1) 107.4(5) C(3)-C(2)-C(21) 128.0(5) C(1)-C(2)-C(21) 124.5(5) C(2)-C(3)-C(4) 107.5(5) C(2)-C(3)-C(23) 128.7(5) C(4)-C(3)-C(23) 123.8(5) N(1)-C(4)-C(5) 125.3(5) N(1)-C(4)-C(3) 108.1(5) C(5)-C(4)-C(3) 126.6(5) C(4)-C(5)-C(6) 128.1(5) N(2)-C(6)-C(5) 125.4(5) N(2)-C(6)-C(7) 108.7(5) C(5)-C(6)-C(7) 125.9(5) C(8)-C(7)-C(6) 107.5(5) C(8)-C(7)-C(25) 127.4(5) C(6)-C(7)-C(25) 125.0(5) C(7)-C(8)-C(9) 107.3(5) C(7)-C(8)-C(27) 128.2(5) C(9)-C(8)-C(27) 124.5(5) N(2)-C(9)-C(10) 125.3(5) N(2)-C(9)-C(8) 107.8(4) C(10)-C(9)-C(8) 126.9(5) C(9)-C(10)-C(11) 127.7(5) N(3)-C(11)-C(10) 125.6(4) N(3)-C(11)-C(12) 107.9(5) C(10)-C(11)-C(12) 126.4(5) C(13)-C(12)-C(11) 107.0(5) C(13)-C(12)-C(29) 128.2(5) C(11)-C(12)-C(29) 124.7(5) C(12)-C(13)-C(14) 108.4(5) C(12)-C(13)-C(31) 128.0(5)
99
C(14)-C(13)-C(31) 123.6(5) N(3)-C(14)-C(15) 125.4(5) N(3)-C(14)-C(13) 107.4(5) C(15)-C(14)-C(13) 127.1(5) C(14)-C(15)-C(16) 128.4(5) N(4)-C(16)-C(15) 125.1(5) N(4)-C(16)-C(17) 108.5(5) C(15)-C(16)-C(17) 126.4(5) C(18)-C(17)-C(16) 107.0(5) C(18)-C(17)-C(33) 127.6(6) C(16)-C(17)-C(33) 125.3(6) C(17)-C(18)-C(19) 107.6(5) C(17)-C(18)-C(35) 128.5(6) C(19)-C(18)-C(35) 123.4(6) N(4)-C(19)-C(20) 126.1(5) N(4)-C(19)-C(18) 107.5(5) C(20)-C(19)-C(18) 126.4(5) C(1)-C(20)-C(19) 128.3(5) C(2)-C(21)-C(22) 111.4(5) C(3)-C(23)-C(24) 112.7(5) C(26)-C(25)-C(7) 112.7(6) C(8)-C(27)-C(28) 112.4(5) C(30)-C(29)-C(12) 113.2(5) C(32)-C(31)-C(13) 112.6(6) C(34)-C(33)-C(17) 112.2(7) C(36)-C(35)-C(18) 104.9(10) C(43B)-Fe(1)-C(45A) 68.2(12) C(43B)-Fe(1)-C(46A) 48.6(13) C(45A)-Fe(1)-C(46A) 41.4(5) C(43B)-Fe(1)-C(39) 114.4(10) C(45A)-Fe(1)-C(39) 151.0(10) C(46A)-Fe(1)-C(39) 116.8(8) C(43B)-Fe(1)-C(40) 109.3(10) C(45A)-Fe(1)-C(40) 168.7(10) C(46A)-Fe(1)-C(40) 145.2(8) C(39)-Fe(1)-C(40) 40.3(2) C(43B)-Fe(1)-C(38) 146.0(11) C(45A)-Fe(1)-C(38) 120.1(8) C(46A)-Fe(1)-C(38) 113.2(8) C(39)-Fe(1)-C(38) 41.2(2) C(40)-Fe(1)-C(38) 68.4(3) C(43B)-Fe(1)-C(44B) 41.2(8) C(45A)-Fe(1)-C(44B) 52.3(9) C(46A)-Fe(1)-C(44B) 66.1(12) C(39)-Fe(1)-C(44B) 148.4(11) C(40)-Fe(1)-C(44B) 118.2(9) C(38)-Fe(1)-C(44B) 170.2(11) C(43B)-Fe(1)-C(41) 134.2(12) C(45A)-Fe(1)-C(41) 132.8(8) C(46A)-Fe(1)-C(41) 174.0(8) C(39)-Fe(1)-C(41) 67.9(2) C(40)-Fe(1)-C(41) 40.8(2) C(38)-Fe(1)-C(41) 67.4(2) C(44B)-Fe(1)-C(41) 112.2(9) C(43B)-Fe(1)-C(43A) 27.7(10) C(45A)-Fe(1)-C(43A) 67.3(8)
C(46A)-Fe(1)-C(43A) 67.6(10) C(39)-Fe(1)-C(43A) 129.3(8) C(40)-Fe(1)-C(43A) 105.2(7) C(38)-Fe(1)-C(43A) 170.4(8) C(44B)-Fe(1)-C(43A) 19.4(6) C(41)-Fe(1)-C(43A) 112.9(8) C(43B)-Fe(1)-C(45B) 67.7(10) C(45A)-Fe(1)-C(45B) 16.0(8) C(46A)-Fe(1)-C(45B) 53.8(10) C(39)-Fe(1)-C(45B) 166.8(12) C(40)-Fe(1)-C(45B) 152.7(12) C(38)-Fe(1)-C(45B) 130.0(10) C(44B)-Fe(1)-C(45B) 41.1(7) C(41)-Fe(1)-C(45B) 120.8(10) C(43A)-Fe(1)-C(45B) 58.8(8) C(43B)-Fe(1)-C(44A) 60.2(9) C(45A)-Fe(1)-C(44A) 41.1(5) C(46A)-Fe(1)-C(44A) 69.8(8) C(39)-Fe(1)-C(44A) 166.7(10) C(40)-Fe(1)-C(44A) 127.8(9) C(38)-Fe(1)-C(44A) 149.2(8) C(44B)-Fe(1)-C(44A) 21.1(6) C(41)-Fe(1)-C(44A) 106.4(6) C(43A)-Fe(1)-C(44A) 40.4(5) C(45B)-Fe(1)-C(44A) 26.0(8) C(43B)-Fe(1)-C(42A) 12.6(12) C(45A)-Fe(1)-C(42A) 68.5(8) C(46A)-Fe(1)-C(42A) 40.5(6) C(39)-Fe(1)-C(42A) 107.7(8) C(40)-Fe(1)-C(42A) 111.7(7) C(38)-Fe(1)-C(42A) 134.2(9) C(44B)-Fe(1)-C(42A) 52.1(12) C(41)-Fe(1)-C(42A) 143.4(9) C(43A)-Fe(1)-C(42A) 40.2(6) C(45B)-Fe(1)-C(42A) 71.6(11) C(44A)-Fe(1)-C(42A) 69.3(8) C(41)-C(37)-C(38) 105.6(5) C(41)-C(37)-Fe(1) 68.4(3) C(38)-C(37)-Fe(1) 67.7(3) C(41)-C(37)-Sn(1) 127.6(4) C(38)-C(37)-Sn(1) 126.0(4) Fe(1)-C(37)-Sn(1) 136.2(2) C(37)-C(38)-C(39) 108.9(5) C(37)-C(38)-Fe(1) 71.7(3) C(39)-C(38)-Fe(1) 69.1(3) C(40)-C(39)-C(38) 107.8(5) C(40)-C(39)-Fe(1) 69.9(3) C(38)-C(39)-Fe(1) 69.6(3) C(39)-C(40)-C(41) 107.6(5) C(39)-C(40)-Fe(1) 69.8(3) C(41)-C(40)-Fe(1) 70.2(3) C(37)-C(41)-C(40) 110.0(5) C(37)-C(41)-Fe(1) 71.5(3) C(40)-C(41)-Fe(1) 69.0(3) C(46A)-C(42A)-C(43A) 106(2) C(46A)-C(42A)-Fe(1) 67.3(14)
100
C(43A)-C(42A)-Fe(1) 69.0(12) C(42A)-C(43A)-C(44A) 112(2) C(42A)-C(43A)-Fe(1) 70.8(12) C(44A)-C(43A)-Fe(1) 70.4(10) C(43A)-C(44A)-C(45A) 104.0(18) C(43A)-C(44A)-Fe(1) 69.2(10) C(45A)-C(44A)-Fe(1) 67.3(12) C(46A)-C(45A)-C(44A) 109.9(15) C(46A)-C(45A)-Fe(1) 69.4(13) C(44A)-C(45A)-Fe(1) 71.6(11) C(42A)-C(46A)-C(45A) 108.4(19) C(42A)-C(46A)-Fe(1) 72.2(13) C(45A)-C(46A)-Fe(1) 69.2(14) C(43B)-C(42B)-C(46B) 105(3) C(43B)-C(42B)-Fe(1) 66.6(16) C(46B)-C(42B)-Fe(1) 71.3(17) C(42B)-C(43B)-C(44B) 112(3) C(42B)-C(43B)-Fe(1) 73.2(16) C(44B)-C(43B)-Fe(1) 71.1(16) C(43B)-C(44B)-C(45B) 104(2) C(43B)-C(44B)-Fe(1) 67.7(16) C(45B)-C(44B)-Fe(1) 70.0(16) C(46B)-C(45B)-C(44B) 109.1(18) C(46B)-C(45B)-Fe(1) 72.4(16) C(44B)-C(45B)-Fe(1) 68.9(14) C(45B)-C(46B)-C(42B) 109(2) C(45B)-C(46B)-Fe(1) 68.1(17) C(42B)-C(46B)-Fe(1) 69.0(17) C(47)-O(1)-Sn(1) 131.2(5) O(1)-C(47)-C(48) 116.3(11)
101
Anisotropic displacement parameters (A^2 x 10^3) for orig2.
The anisotropic displacement factor exponent takes the form:
-2 pi^2 [ h^2 a*^2 U11 + ... + 2 h k a* b* U12 ]
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U11 U22 U33 U23 U13 U12 ______________________________________________________________________________
Sn(1) 55(1) 50(1) 69(1) -22(1) -9(1) -8(1) N(1) 64(3) 57(3) 74(3) -22(2) -3(2) -13(2) N(2) 57(3) 48(3) 78(3) -18(2) -14(2) -9(2) N(3) 57(3) 48(3) 78(3) -24(2) -10(2) -10(2) N(4) 66(3) 58(3) 78(3) -31(2) -3(2) -6(2) C(1) 67(4) 62(4) 65(3) -18(3) -3(3) -18(3) C(2) 74(4) 71(4) 63(3) -13(3) -8(3) -21(3) C(3) 71(4) 61(4) 64(3) -9(3) -10(3) -22(3) C(4) 72(4) 54(3) 67(3) -13(3) -20(3) -15(3) C(5) 61(4) 56(3) 78(4) -17(3) -14(3) -7(3) C(6) 60(3) 49(3) 75(3) -19(3) -19(3) -1(3) C(7) 57(3) 58(3) 89(4) -26(3) -17(3) 0(3) C(8) 52(3) 63(4) 85(4) -25(3) -16(3) 0(3) C(9) 47(3) 64(4) 71(3) -25(3) -17(3) -2(3) C(10) 61(3) 54(3) 73(3) -22(3) -14(3) -11(3) C(11) 60(4) 63(4) 68(3) -19(3) -11(3) -20(3) C(12) 71(4) 62(4) 65(3) -18(3) -14(3) -21(3) C(13) 79(4) 52(3) 75(4) -16(3) -18(3) -20(3) C(14) 72(4) 54(3) 73(3) -22(3) -19(3) -12(3) C(15) 74(4) 59(3) 78(4) -28(3) -16(3) -4(3) C(16) 66(4) 62(4) 79(4) -34(3) -9(3) -1(3) C(17) 85(4) 67(4) 95(4) -37(3) -6(3) -3(3) C(18) 69(4) 90(5) 103(5) -45(4) 14(3) -3(4) C(19) 59(4) 77(4) 82(4) -35(3) -3(3) 0(3) C(20) 74(4) 64(4) 83(4) -29(3) 0(3) -14(3) C(21) 81(4) 82(4) 85(4) -19(3) 3(3) -28(3) C(22) 87(5) 132(6) 109(5) -27(5) -12(4) -33(4) C(23) 93(4) 62(4) 93(4) -9(3) -6(3) -28(3) C(24) 147(7) 95(5) 116(6) -38(4) -26(5) -43(5) C(25) 66(4) 58(4) 125(5) -25(4) -12(3) 5(3) C(26) 144(7) 81(5) 161(8) -29(5) -67(6) -1(5) C(27) 58(4) 70(4) 112(5) -31(3) -15(3) -2(3) C(28) 95(5) 96(5) 113(6) -40(4) 10(4) -9(4) C(29) 73(4) 71(4) 78(4) -18(3) -9(3) -26(3) C(30) 74(4) 127(6) 103(5) -44(4) -11(4) -29(4) C(31) 110(5) 57(4) 109(5) -23(3) -10(4) -27(3) C(32) 179(9) 95(6) 182(9) -61(6) -54(7) -26(6) C(33) 115(6) 82(5) 134(6) -55(5) 15(5) -8(4) C(34) 338(18) 105(7) 161(10) -65(7) -30(11) -6(9) C(35) 222(11) 89(6) 115(7) -35(5) 51(7) 11(6) C(36) 142(9) 210(13) 205(13) -83(10) 12(9) -15(8) Fe(1) 68(1) 71(1) 77(1) -34(1) -22(1) 7(1) C(37) 53(3) 51(3) 66(3) -20(3) -6(2) 0(2) C(38) 57(3) 85(4) 83(4) -23(3) -11(3) -23(3)
102
C(39) 64(4) 99(5) 99(5) -43(4) -26(3) 4(4) C(40) 91(4) 61(4) 87(4) -20(3) -28(4) 11(3) C(41) 69(4) 64(4) 84(4) -21(3) -16(3) -8(3) C(42A) 133(17) 128(18) 118(17) -98(15) -65(13) 50(14) C(43A) 101(18) 181(18) 75(11) -59(11) -24(11) 39(14) C(44A) 83(12) 148(19) 96(16) -65(15) -16(11) 18(12) C(45A) 108(19) 94(17) 105(15) -66(11) -45(13) 28(13) C(46A) 148(19) 102(14) 165(19) -79(14) -91(14) 53(13) C(42B) 121(19) 100(20) 150(20) -67(16) -66(17) 20(15) C(43B) 92(18) 140(20) 121(19) -52(17) -46(15) 1(16) C(44B) 75(17) 151(19) 80(20) -53(16) -12(15) 12(14) C(45B) 75(14) 90(19) 87(16) -35(14) -24(12) 13(13) C(46B) 110(20) 52(12) 160(20) -54(12) -36(16) 16(12) O(1) 88(3) 73(3) 79(3) -16(2) -15(2) -15(2) C(47) 164(9) 366(18) 79(6) -63(8) -60(6) -51(11) C(48) 138(7) 132(7) 114(6) -33(5) -48(5) -18(5) _______________________________________________________________________
CIF Information for Compound 5:
Crystal data and structure refinement
Empirical formula C56 H62 Fe2 N4 Sn Formula weight 1021.49 Temperature 123(2) K Wavelength 0.71075 A Crystal system, space group Triclinic, P-1 Unit cell dimensions a = 9.858(3) A alpha = 68.393(6) deg. b = 10.313(3) A beta = 85.796(6) deg. c = 13.370(4) A gamma = 66.759(5) deg. Volume 1157.1(6) A^3 Z, Calculated density 1, 1.466 Mg/m^3 Absorption coefficient 1.197 mm^-1 F(000) 528 Crystal size 0.20 x 0.20 x 0.20 mm Theta range for data collection 3.25 to 27.48 deg. Limiting indices -12<=h<=12, -12<=k<=12, -17<=l<=17 Reflections collected / unique 27643 / 5107 [R(int) = 0.1441] Completeness to theta = 27.48 96.1 % Absorption correction Semi-empirical from equivalents Max. and min. transmission 0.7957 and 0.7957 Refinement method Full-matrix least-squares on F^2 Data / restraints / parameters 5107 / 0 / 286 Goodness-of-fit on F^2 1.026 Final R indices [I>2sigma(I)] R1 = 0.0963, wR2 = 0.2459 R indices (all data) R1 = 0.1529, wR2 = 0.2831 Largest diff. peak and hole 1.638 and -1.550 e.A^-3
103
Atomic coordinates ( x 10^4) and equivalent isotropic displacement parameters (A^2 x 10^3)
U(eq) is defined as one third of the trace of the orthogonalized Uij tensor.
______________________________________________________________________________ x y z U(eq) x y z U(eq ______________________________________________________________________________ Sn(1) 0 0 0 49(1) Fe(1) 2954(2) 218(2) -2249(1) 70(1) N(2) -390(8) 1845(8) 457(5) 46(2) N(9) -1708(8) 1396(8) -1237(5) 47(2) C(3) 1507(10) 774(11) -1083(7) 51(2) C(4) 2988(15) 566(14 -846(9) 77(3) C(5) -3823(12) 6009(12) 760(10) 70(3) C(6) -3310(13) 5959(12) -3895(7) 64(3) C(7) -438(14) 3319(13) 3240(8) 67(3) C(8)-2594(13) 2217(13) -4664(8) 67(3) C(10)-3340(10) 3503(10) -2553(6) 48(2) C(11) -1325(10) 4226(10) 525(7) 47(2) C(12) -3709(11) 2314(11) -3835(7) 54(2) C(13) -2082(9) 974(10) -2017(6) 46(2) C(14) -4240(11) 5153(10) -3185(7)55(2) C(15) -3107(10) 2310(10) -2842(7) 48(2)
C(16) 264(11) 3744(12 2175(7) 53(2) C(17) -2452(10) 2946(10) -1545(7)46(2) C(18) -1405(10) 3302(10) -45(6) 45(2) C(19) -1476(10) -519(10) -1998(7) 47(2) C(20) -2335(10) 3765(10) -963(7)46(2) C(21) -2341(11) 5859(10) 267(8) 52(2) C(22) -248(10) 3324(10) 1341(6) 46(2) C(24) 364(10) 1810(11) 1306(7) 48(2) C(25) 1152(16) 2021(15) -2175(10) 82(3) C(26) 2819(17) -1575(17) -2423(12) 82(4) C(28) 3970(30) -165(19) -3529(13) 117(7) C(29) 4150(20) -1976(17) -1988(14) 105(5) C(33) 2560(20) -320(30) -3478(18) 130(8) C(23) 4853(17) -1208(18) -2568(15) 94(4) C(30) 2374(17) 2448(15) -2513(11) 85(4) C(31) 3538(16) 1522(16) -1703(11) 82(3)
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Bond lengths [A] and angles [deg]
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Sn(1)-N(9)#1 2.094(7) Sn(1)-N(9) 2.094(7) Sn(1)-N(2) 2.094(7) Sn(1)-N(2)#1 2.094(7) Sn(1)-C(3)#1 2.170(10) Sn(1)-C(3) 2.170(10) Fe(1)-C(26) 2.002(13) Fe(1)-C(29) 2.002(14) Fe(1)-C(28) 2.005(14) Fe(1)-C(23) 2.006(14) Fe(1)-C(31) 2.018(13) Fe(1)-C(33) 2.023(13) Fe(1)-C(25) 2.031(13) Fe(1)-C(30) 2.033(13) Fe(1)-C(4) 2.041(11) Fe(1)-C(3) 2.117(9) N(2)-C(18) 1.371(11) N(2)-C(24) 1.384(11) N(9)-C(17) 1.378(11) N(9)-C(13) 1.388(10) C(3)-C(4) 1.431(16)
C(3)-C(25) 1.499(16) C(4)-C(31) 1.442(18) C(5)-C(21) 1.532(14) C(6)-C(14) 1.525(14) C(7)-C(16) 1.528(13) C(8)-C(12) 1.505(14) C(10)-C(15) 1.353(13) C(10)-C(17) 1.456(11) C(10)-C(14) 1.502(12) C(11)-C(22) 1.352(12) C(11)-C(18) 1.447(12) C(11)-C(21) 1.500(12) C(12)-C(15) 1.491(12) C(13)-C(19) 1.406(13) C(13)-C(15) 1.443(12) C(16)-C(22) 1.515(12) C(17)-C(20) 1.380(12) C(18)-C(20) 1.401(11) C(19)-C(24)#1 1.385(12) C(22)-C(24) 1.453(13) C(24)-C(19)#1 1.385(12)
104
C(25)-C(30) 1.429(19) C(26)-C(29) 1.32(2) C(26)-C(33) 1.48(3) C(28)-C(23) 1.41(2) C(28)-C(33) 1.45(2) C(29)-C(23) 1.27(2) C(30)-C(31) 1.399(19) N(9)#1-Sn(1)-N(9) 179.999(1) N(9)#1-Sn(1)-N(2) 90.4(3) N(9)-Sn(1)-N(2) 89.6(3) N(9)#1-Sn(1)-N(2)#1 89.6(3) N(9)-Sn(1)-N(2)#1 90.4(3) N(2)-Sn(1)-N(2)#1 180.0 N(9)#1-Sn(1)-C(3)#1 88.7(3) N(9)-Sn(1)-C(3)#1 91.3(3) N(2)-Sn(1)-C(3)#1 94.2(3) N(2)#1-Sn(1)-C(3)#1 85.8(3) N(9)#1-Sn(1)-C(3) 91.3(3) N(9)-Sn(1)-C(3) 88.7(3) N(2)-Sn(1)-C(3) 85.8(3) N(2)#1-Sn(1)-C(3) 94.2(3) C(3)#1-Sn(1)-C(3) 180.000(1) C(26)-Fe(1)-C(29) 38.5(6) C(26)-Fe(1)-C(28) 68.2(6) C(29)-Fe(1)-C(28) 65.7(7) C(26)-Fe(1)-C(23) 65.4(6) C(29)-Fe(1)-C(23) 36.9(6) C(28)-Fe(1)-C(23) 41.1(7) C(26)-Fe(1)-C(31) 162.6(7) C(29)-Fe(1)-C(31) 125.6(7) C(28)-Fe(1)-C(31) 115.5(7) C(23)-Fe(1)-C(31) 105.4(6) C(26)-Fe(1)-C(33) 43.0(7) C(29)-Fe(1)-C(33) 68.9(7) C(28)-Fe(1)-C(33) 42.2(7) C(23)-Fe(1)-C(33) 70.2(7) C(31)-Fe(1)-C(33) 150.6(9) C(26)-Fe(1)-C(25) 123.2(6) C(29)-Fe(1)-C(25) 155.5(7) C(28)-Fe(1)-C(25) 130.1(7) C(23)-Fe(1)-C(25) 167.4(6) C(31)-Fe(1)-C(25) 68.7(6) C(33)-Fe(1)-C(25) 109.0(6) C(26)-Fe(1)-C(30) 156.9(7) C(29)-Fe(1)-C(30) 162.2(8) C(28)-Fe(1)-C(30) 107.6(6) C(23)-Fe(1)-C(30) 127.3(6) C(31)-Fe(1)-C(30) 40.4(5) C(33)-Fe(1)-C(30) 118.2(8) C(25)-Fe(1)-C(30) 41.2(5) C(26)-Fe(1)-C(4) 127.3(6) C(29)-Fe(1)-C(4) 109.0(6) C(28)-Fe(1)-C(4) 150.2(8) C(23)-Fe(1)-C(4) 116.6(6) C(31)-Fe(1)-C(4) 41.6(5) C(33)-Fe(1)-C(4) 166.5(8)
C(25)-Fe(1)-C(4) 67.0(5) C(30)-Fe(1)-C(4) 68.0(5) C(26)-Fe(1)-C(3) 108.2(5) C(29)-Fe(1)-C(3) 118.5(6) C(28)-Fe(1)-C(3) 169.1(7) C(23)-Fe(1)-C(3) 148.0(6) C(31)-Fe(1)-C(3) 71.2(5) C(33)-Fe(1)-C(3) 128.1(6) C(25)-Fe(1)-C(3) 42.3(4) C(30)-Fe(1)-C(3) 71.4(5) C(4)-Fe(1)-C(3) 40.2(4) C(18)-N(2)-C(24) 108.0(7) C(18)-N(2)-Sn(1) 126.3(6) C(24)-N(2)-Sn(1) 125.7(6) C(17)-N(9)-C(13) 107.8(7) C(17)-N(9)-Sn(1) 125.7(6) C(13)-N(9)-Sn(1) 125.4(6) C(4)-C(3)-C(25) 100.1(10) C(4)-C(3)-Fe(1) 67.0(6) C(25)-C(3)-Fe(1) 65.8(6) C(4)-C(3)-Sn(1) 129.1(7) C(25)-C(3)-Sn(1) 128.6(8) Fe(1)-C(3)-Sn(1) 140.8(5) C(3)-C(4)-C(31) 113.9(11) C(3)-C(4)-Fe(1) 72.7(6) C(31)-C(4)-Fe(1) 68.3(7) C(12)-C(8)-H(8C) 109.5 C(15)-C(10)-C(17) 108.4(8) C(15)-C(10)-C(14) 127.4(8) C(17)-C(10)-C(14) 124.0(8) C(22)-C(11)-C(18) 107.5(7) C(22)-C(11)-C(21) 127.8(8) C(18)-C(11)-C(21) 124.6(8) C(15)-C(12)-C(8) 111.7(8) N(9)-C(13)-C(19) 123.8(7) N(9)-C(13)-C(15) 109.0(8) C(19)-C(13)-C(15) 127.2(7) C(10)-C(14)-C(6) 112.6(8) C(10)-C(15)-C(13) 107.0(7) C(10)-C(15)-C(12) 128.5(8) C(13)-C(15)-C(12) 124.4(8) C(22)-C(16)-C(7) 112.5(8) N(9)-C(17)-C(20) 123.9(7) N(9)-C(17)-C(10) 107.8(8) C(20)-C(17)-C(10) 128.3(8) N(2)-C(18)-C(20) 123.6(8) N(2)-C(18)-C(11) 108.8(7) C(20)-C(18)-C(11) 127.6(8) C(24)#1-C(19)-C(13) 130.1(8) C(17)-C(20)-C(18) 130.2(8) C(11)-C(21)-C(5) 111.5(8) C(11)-C(22)-C(24) 107.7(7) C(11)-C(22)-C(16) 128.2(8) C(24)-C(22)-C(16) 124.1(8) N(2)-C(24)-C(19)#1 124.3(9) N(2)-C(24)-C(22) 107.9(8)
105
C(19)#1-C(24)-C(22) 127.8(8) C(30)-C(25)-C(3) 111.6(12) C(30)-C(25)-Fe(1) 69.5(8) C(3)-C(25)-Fe(1) 71.9(6) C(29)-C(26)-C(33) 108.9(14) C(29)-C(26)-Fe(1) 70.8(9) C(33)-C(26)-Fe(1) 69.3(7) C(23)-C(28)-C(33) 108.5(15) C(23)-C(28)-Fe(1) 69.5(8) C(33)-C(28)-Fe(1) 69.6(8) C(23)-C(29)-C(26) 113.6(17) C(23)-C(29)-Fe(1) 71.7(9) C(26)-C(29)-Fe(1) 70.8(9) C(28)-C(33)-C(26) 100.4(14) C(28)-C(33)-Fe(1) 68.2(8) C(26)-C(33)-Fe(1) 67.7(8) C(29)-C(23)-C(28) 108.6(16) C(29)-C(23)-Fe(1) 71.4(9) C(28)-C(23)-Fe(1) 69.4(9) C(31)-C(30)-C(25) 107.8(12) C(31)-C(30)-Fe(1) 69.2(8) C(25)-C(30)-Fe(1) 69.3(7) C(30)-C(31)-C(4) 106.6(12) C(30)-C(31)-Fe(1) 70.4(8) C(4)-C(31)-Fe(1) 70.0(7)
106
Symmetry transformations used to generate equivalent atoms:
#1 -x,-y,-z
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Anisotropic displacement parameters (A^2 x 10^3)
The anisotropic displacement factor exponent takes the form:
-2 pi^2 [ h^2 a*^2 U11 + ... + 2 h k a* b* U12 ]
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U11 U22 U33 U23 U13 U12 ______________________________________________________________________________ Sn(1) 46(1) 51(1) 41(1) -17(1) -13(1) -9(1) Fe(1) 69(1) 77(1) 60(1) -26(1) 7(1) -27(1) N(2) 44(4) 56(4) 31(4) -15(3) 2(3) -15(3) N(9) 49(4) 56(4) 33(4) -15(3) -1(3) -18(3) C(3) 35(5) 74(6) 35(4) -25(4) 2(3) -7(4) C(4) 93(9) 75(7) 56(6) -27(5) 4(6) -23(6) C(5) 60(7) 58(6) 82(8) -27(5) 15(6) -15(5) C(6) 81(8) 69(6) 37(5) -9(4) -1(5) -34(6) C(7) 79(8) 85(7) 52(6) -34(5) 18(5) -41(6) C(8) 78(8) 77(7) 41(5) -21(5) -6(5) -24(6) C(10) 41(5) 62(5) 30(4) -9(4) -2(3) -14(4) C(11) 47(5) 52(5) 36(4) -13(4) 7(4) -17(4) C(12) 52(6) 65(5) 31(4) -7(4) -10(4) -17(4) C(13) 38(5) 62(5) 34(4) -16(4) -1(3) -18(4) C(14) 50(6) 60(5) 38(5) -9(4) -8(4) -14(4) C(15) 47(5) 61(5) 32(4) -16(4) 8(4) -19(4) C(16) 57(6) 68(6) 38(5) -21(4) 7(4) -27(5) C(17) 40(5) 55(5) 35(4) -9(4) 0(3) -16(4) C(18) 41(5) 52(5) 33(4) -8(3) 4(3) -17(4) C(19) 41(5) 68(5) 36(4) -17(4) 2(3) -25(4) C(20) 38(5) 49(4) 40(4) -8(4) 5(4) -14(4) C(21) 51(6) 54(5) 47(5) -17(4) 7(4) -20(4) C(22) 50(5) 59(5) 32(4) -19(4) 14(4) -26(4) C(24) 44(5) 65(5) 35(4) -14(4) 6(4) -26(4) C(25) 84(9) 85(8) 71(8) -34(6) 9(7) -23(7) C(26) 85(10) 104(10) 82(9) -43(8) 33(8) -57(8) C(28) 200(20) 103(11) 69(9) -45(8) 58(11) -81(13) C(29) 111(13) 78(9) 106(12) -40(8) -5(10) -12(9) C(33) 97(12) 179(19) 164(19) -142(17) -3(12) -31(12) C(23) 74(9) 95(10) 131(14) -60(10) 40(9) -39(8) C(30) 106(11) 74(7) 70(8) -26(6) 29(8) -35(7) C(31) 78(9) 101(9) 78(8) -41(7) 14(7) -40(7) ______________________________________________________________________________
107
CIF Information for Compound 6:
Empirical formula C70.91 H62.75 Cl Fe4 In N4 Formula weight 1344.59 Temperature 123(2) K Wavelength 0.71075 A Crystal system, space group Triclinic, P-1 Unit cell dimensions a = 11.2415(3) A alpha = 82.613(6) deg. b = 15.3866(3) A beta = 81.185(6) deg. c = 16.2741(11) A gamma = 76.854(5) deg. Volume 2695.9(2) A^3 Z, Calculated density 2, 1.656 Mg/m^3 Absorption coefficient 1.573 mm^-1 F(000) 1372 Crystal size 0.20 x 0.20 x 0.20 mm Theta range for data collection 3.00 to 27.48 deg. Limiting indices -14<=h<=14, -19<=k<=19, -21<=l<=21 Reflections collected / unique 73246 / 12287 [R(int) = 0.0380] Completeness to theta = 27.48 99.5 % Absorption correction Semi-empirical from equivalents Max. and min. transmission 0.7438 and 0.7438 Refinement method Full-matrix least-squares on F^2 Data / restraints / parameters 12287 / 0 / 714 Goodness-of-fit on F^2 1.132 Final R indices [I>2sigma(I)] R1 = 0.0391, wR2 = 0.0967 R indices (all data) R1 = 0.0437, wR2 = 0.0987 Largest diff. peak and hole 0.595 and -0.450 e.A^-3
Atomic coordinates ( x 10^4) and equivalent isotropic displacement parameters (A^2 x 10^3)
U(eq) is defined as one third of the trace of the orthogonalized Uij tensor.
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x y z U(eq) x y z U(eq)
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In(1A) 7235(1) 2011(1) 2963(1) 22(1) Cl(1A) 7930(1) 1865(1) 4303(1) 37(1) C(61) 6915(6) 1269(5) 150(4) 78(2) C(62) 6545(8) 443(6) 249(6) 95(2) C(63) 5549(8) 353(6) 857(5) 93(2) C(64) 4941(7) 1066(5) 1333(5) 82(2) C(65) 5348(6) 1864(5) 1207(4) 70(2) C(66) 6330(6) 1984(5) 619(4) 65(2)
C(67) 6741(7) 2853(5) 469(4) 76(2) In(1B) 6798(1) 2147(1) 2225(1) 24(1) Cl(1B) 5938(7) 2493(5) 950(5) 55(2) Fe(1) 4710(1) 6420(1) 2763(1) 26(1) Fe(2) 2146(1) 331(1) 3817(1) 25(1) Fe(3) 9297(1) -2297(1) 2462(1) 24(1) Fe(4) 11823(1) 3930(1) 1073(1) 26(1) N(1) 5358(2) 2687(2) 3280(2) 26(1)
108
N(2) 6529(2) 825(2) 2933(2) 29(1) N(3) 8675(2) 1462(2) 2004(2) 26(1) N(4) 7535(2) 3303(2) 2405(2) 26(1) C(1) 5062(3) 3556(2) 3499(2) 26(1) C(2) 4018(3) 3642(2) 4132(2) 32(1) C(3) 3673(3) 2838(2) 4275(2) 32(1) C(4) 4504(3) 2241(2) 3739(2) 27(1) C(5) 4468(3) 1329(2) 3715(2) 25(1) C(6) 5430(3) 672(2) 3359(2) 27(1) C(7) 5428(3) -264(2) 3378(2) 29(1) C(8) 6513(3) -660(2) 2967(2) 29(1) C(9) 7209(3) 19(2) 2667(2) 28(1) C(10) 8329(3) -97(2) 2139(2) 26(1) C(11) 8926(3) 601(2) 1768(2) 25(1) C(12) 9873(3) 530(2) 1067(2) 27(1) C(13) 10208(3) 1337(2) 892(2) 26(1) C(14) 9468(3) 1923(2) 1488(2) 25(1) C(15) 9525(3) 2830(2) 1514(2) 25(1) C(16) 8608(3) 3461(2) 1934(2) 26(1) C(17) 8591(3) 4406(2) 1897(2) 29(1) C(18) 7515(3) 4800(2) 2322(2) 29(1) C(19) 6850(3) 4110(2) 2658(2) 26(1) C(20) 5692(3) 4246(2) 3164(2) 26(1) C(21) 5092(3) 5153(2) 3414(2) 28(1) C(22) 3795(3) 5531(2) 3467(2) 32(1) C(23) 3548(3) 6345(2) 3845(2) 37(1) C(24) 4686(3) 6492(2) 4019(2) 34(1) C(25) 5626(3) 5771(2) 3750(2) 29(1) C(26) 5855(3) 6943(2) 1814(2) 33(1) C(27) 5278(3) 6326(2) 1518(2) 35(1) C(28) 3982(3) 6644(2) 1659(2) 37(1) C(29) 3751(3) 7457(2) 2047(2) 36(1)
C(30) 4901(3) 7638(2) 2137(2) 33(1) C(31) 3302(3) 1081(2) 4130(2) 27(1) C(32) 3121(3) 379(2) 4773(2) 30(1) C(33) 1837(3) 492(2) 5052(2) 36(1) C(34) 1213(3) 1260(2) 4592(2) 35(1) C(35) 2105(3) 1613(2) 4022(2) 30(1) C(36) 2803(3) -274(2) 2733(2) 31(1) C(37) 2588(3) -922(2) 3414(2) 33(1) C(38) 1320(3) -693(2) 3742(2) 34(1) C(39) 761(3) 91(2) 3271(2) 36(1) C(40) 1676(3) 348(2) 2649(2) 34(1) C(41) 8931(3) -1000(2) 1862(2) 26(1) C(42) 10226(3) -1378(2) 1815(2) 28(1) C(43) 10486(3) -2169(2) 1400(2) 32(1) C(44) 9355(3) -2297(2) 1203(2) 32(1) C(45) 8393(3) -1592(2) 1492(2) 29(1) C(46) 9111(3) -3547(2) 2984(2) 31(1) C(47) 10237(3) -3374(2) 3145(2) 32(1) C(48) 9940(3) -2604(2) 3601(2) 33(1) C(49) 8642(3) -2308(2) 3711(2) 32(1) C(50) 8127(3) -2892(2) 3331(2) 31(1) C(51) 10595(3) 3115(2) 975(2) 26(1) C(52) 11847(3) 2624(2) 928(2) 28(1) C(53) 12554(3) 3011(2) 238(2) 30(1) C(54) 11754(3) 3760(2) -135(2) 30(1) C(55) 10556(3) 3830(2) 321(2) 26(1) C(56) 11498(3) 4487(3) 2188(2) 39(1) C(57) 12701(4) 3937(3) 2089(2) 45(1) C(58) 13350(3) 4287(3) 1348(3) 48(1) C(59) 12548(4) 5045(3) 991(3) 45(1) C(60) 11410(3) 5169(2) 1510(2) 38(1)
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Bond lengths [A] and angles [deg]
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In(1A)-N(1) 2.146(2) In(1A)-N(4) 2.153(2) In(1A)-N(2) 2.158(2) In(1A)-N(3) 2.171(3) In(1A)-Cl(1A) 2.3940(10) C(61)-C(66) 1.399(10) C(61)-C(62) 1.408(10) C(62)-C(63) 1.395(11) C(63)-C(64) 1.410(11) C(64)-C(65) 1.386(9) C(65)-C(66) 1.375(8) C(66)-C(67) 1.491(9) In(1B)-N(3) 2.132(3) In(1B)-N(4) 2.195(3) In(1B)-N(2) 2.265(3) In(1B)-N(1) 2.273(3)
In(1B)-Cl(1B) 2.370(7) Fe(1)-C(22) 2.030(3) Fe(1)-C(23) 2.033(3) Fe(1)-C(27) 2.043(3) Fe(1)-C(28) 2.044(3) Fe(1)-C(29) 2.047(3) Fe(1)-C(30) 2.054(3) Fe(1)-C(26) 2.057(3) Fe(1)-C(24) 2.058(3) Fe(1)-C(25) 2.066(3) Fe(1)-C(21) 2.082(3) Fe(2)-C(33) 2.025(3) Fe(2)-C(38) 2.026(3) Fe(2)-C(34) 2.028(3) Fe(2)-C(39) 2.029(3) Fe(2)-C(35) 2.032(3)
109
Fe(2)-C(40) 2.044(3) Fe(2)-C(37) 2.045(3) Fe(2)-C(32) 2.054(3) Fe(2)-C(36) 2.057(3) Fe(2)-C(31) 2.079(3) Fe(3)-C(43) 2.033(3) Fe(3)-C(42) 2.037(3) Fe(3)-C(44) 2.040(3) Fe(3)-C(46) 2.042(3) Fe(3)-C(47) 2.046(3) Fe(3)-C(48) 2.052(3) Fe(3)-C(49) 2.052(3) Fe(3)-C(50) 2.053(3) Fe(3)-C(45) 2.063(3) Fe(3)-C(41) 2.087(3) Fe(4)-C(54) 2.031(3) Fe(4)-C(53) 2.037(3) Fe(4)-C(59) 2.041(3) Fe(4)-C(58) 2.044(4) Fe(4)-C(52) 2.047(3) Fe(4)-C(60) 2.049(3) Fe(4)-C(57) 2.054(4) Fe(4)-C(56) 2.054(3) Fe(4)-C(55) 2.057(3) Fe(4)-C(51) 2.100(3) N(1)-C(4) 1.377(4) N(1)-C(1) 1.382(4) N(2)-C(6) 1.374(4) N(2)-C(9) 1.384(4) N(3)-C(14) 1.381(4) N(3)-C(11) 1.383(4) N(4)-C(19) 1.379(4) N(4)-C(16) 1.380(4) C(1)-C(20) 1.414(4) C(1)-C(2) 1.431(4) C(2)-C(3) 1.361(4) C(3)-C(4) 1.429(4) C(4)-C(5) 1.418(4) C(5)-C(6) 1.411(4) C(5)-C(31) 1.486(4) C(6)-C(7) 1.436(4) C(7)-C(8) 1.351(4) C(8)-C(9) 1.436(4) C(9)-C(10) 1.401(4) C(10)-C(11) 1.416(4) C(10)-C(41) 1.494(4) C(11)-C(12) 1.433(4) C(12)-C(13) 1.361(4) C(13)-C(14) 1.442(4) C(14)-C(15) 1.418(4) C(15)-C(16) 1.404(4) C(15)-C(51) 1.492(4) C(16)-C(17) 1.444(4) C(17)-C(18) 1.352(4) C(18)-C(19) 1.440(4) C(19)-C(20) 1.418(4)
C(20)-C(21) 1.484(4) C(21)-C(25) 1.434(4) C(21)-C(22) 1.435(4) C(22)-C(23) 1.419(5) C(23)-C(24) 1.424(5) C(24)-C(25) 1.411(5) C(26)-C(30) 1.421(5) C(26)-C(27) 1.430(5) C(27)-C(28) 1.421(5) C(28)-C(29) 1.428(5) C(29)-C(30) 1.414(5) C(31)-C(35) 1.431(4) C(31)-C(32) 1.431(4) C(32)-C(33) 1.423(5) C(33)-C(34) 1.417(5) C(34)-C(35) 1.412(4) C(36)-C(40) 1.418(5) C(36)-C(37) 1.422(5) C(37)-C(38) 1.424(5) C(38)-C(39) 1.416(5) C(39)-C(40) 1.414(5) C(41)-C(42) 1.433(4) C(41)-C(45) 1.436(4) C(42)-C(43) 1.418(4) C(43)-C(44) 1.420(5) C(44)-C(45) 1.418(5) C(46)-C(50) 1.417(5) C(46)-C(47) 1.419(5) C(47)-C(48) 1.428(4) C(48)-C(49) 1.416(5) C(49)-C(50) 1.419(4) C(51)-C(55) 1.427(4) C(51)-C(52) 1.434(4) C(52)-C(53) 1.420(4) C(53)-C(54) 1.422(4) C(54)-C(55) 1.423(4) C(56)-C(60) 1.420(5) C(56)-C(57) 1.421(5) C(57)-C(58) 1.420(6) C(58)-C(59) 1.421(6) C(59)-C(60) 1.410(5) N(1)-In(1A)-N(4) 85.75(9) N(1)-In(1A)-N(2) 86.70(9) N(4)-In(1A)-N(2) 150.45(10) N(1)-In(1A)-N(3) 147.85(10) N(4)-In(1A)-N(3) 85.80(9) N(2)-In(1A)-N(3) 85.55(9) N(1)-In(1A)-Cl(1A) 99.30(8) N(4)-In(1A)-Cl(1A) 103.94(8) N(2)-In(1A)-Cl(1A) 105.46(8) N(3)-In(1A)-Cl(1A) 112.85(7) C(66)-C(61)-C(62) 123.3(7) C(63)-C(62)-C(61) 116.7(8) C(62)-C(63)-C(64) 121.0(8) C(65)-C(64)-C(63) 119.6(7) C(66)-C(65)-C(64) 121.6(8)
110
C(65)-C(66)-C(61) 117.7(7) C(65)-C(66)-C(67) 121.4(8) C(61)-C(66)-C(67) 120.9(6) N(3)-In(1B)-N(4) 85.73(10) N(3)-In(1B)-N(2) 83.88(10) N(4)-In(1B)-N(2) 138.40(12) N(3)-In(1B)-N(1) 140.66(11) N(4)-In(1B)-N(1) 81.79(10) N(2)-In(1B)-N(1) 81.25(10) N(3)-In(1B)-Cl(1B) 110.0(2) N(4)-In(1B)-Cl(1B) 106.9(2) N(2)-In(1B)-Cl(1B) 114.5(2) N(1)-In(1B)-Cl(1B) 109.3(2) C(22)-Fe(1)-C(23) 40.88(13) C(22)-Fe(1)-C(27) 121.73(14) C(23)-Fe(1)-C(27) 155.72(15) C(22)-Fe(1)-C(28) 104.04(15) C(23)-Fe(1)-C(28) 118.32(15) C(27)-Fe(1)-C(28) 40.68(14) C(22)-Fe(1)-C(29) 119.00(14) C(23)-Fe(1)-C(29) 103.24(15) C(27)-Fe(1)-C(29) 68.46(14) C(28)-Fe(1)-C(29) 40.86(13) C(22)-Fe(1)-C(30) 155.84(13) C(23)-Fe(1)-C(30) 121.03(14) C(27)-Fe(1)-C(30) 68.15(13) C(28)-Fe(1)-C(30) 68.23(14) C(29)-Fe(1)-C(30) 40.35(13) C(22)-Fe(1)-C(26) 160.01(13) C(23)-Fe(1)-C(26) 159.07(13) C(27)-Fe(1)-C(26) 40.83(13) C(28)-Fe(1)-C(26) 68.61(15) C(29)-Fe(1)-C(26) 68.35(14) C(30)-Fe(1)-C(26) 40.45(13) C(22)-Fe(1)-C(24) 68.50(14) C(23)-Fe(1)-C(24) 40.75(14) C(27)-Fe(1)-C(24) 162.94(14) C(28)-Fe(1)-C(24) 155.24(14) C(29)-Fe(1)-C(24) 120.57(14) C(30)-Fe(1)-C(24) 108.44(13) C(26)-Fe(1)-C(24) 125.81(14) C(22)-Fe(1)-C(25) 68.16(13) C(23)-Fe(1)-C(25) 67.97(14) C(27)-Fe(1)-C(25) 127.43(13) C(28)-Fe(1)-C(25) 160.87(13) C(29)-Fe(1)-C(25) 158.25(13) C(30)-Fe(1)-C(25) 125.89(13) C(26)-Fe(1)-C(25) 112.48(13) C(24)-Fe(1)-C(25) 40.03(13) C(22)-Fe(1)-C(21) 40.83(12) C(23)-Fe(1)-C(21) 68.58(13) C(27)-Fe(1)-C(21) 109.67(13) C(28)-Fe(1)-C(21) 122.45(13) C(29)-Fe(1)-C(21) 156.80(13) C(30)-Fe(1)-C(21) 162.26(13) C(26)-Fe(1)-C(21) 126.38(13)
C(24)-Fe(1)-C(21) 68.14(13) C(25)-Fe(1)-C(21) 40.45(12) C(33)-Fe(2)-C(38) 103.13(14) C(33)-Fe(2)-C(34) 40.92(15) C(38)-Fe(2)-C(34) 115.92(13) C(33)-Fe(2)-C(39) 118.39(14) C(38)-Fe(2)-C(39) 40.88(14) C(34)-Fe(2)-C(39) 101.42(14) C(33)-Fe(2)-C(35) 68.51(14) C(38)-Fe(2)-C(35) 152.44(13) C(34)-Fe(2)-C(35) 40.70(13) C(39)-Fe(2)-C(35) 118.39(14) C(33)-Fe(2)-C(40) 155.88(14) C(38)-Fe(2)-C(40) 68.38(14) C(34)-Fe(2)-C(40) 120.81(15) C(39)-Fe(2)-C(40) 40.62(14) C(35)-Fe(2)-C(40) 108.06(14) C(33)-Fe(2)-C(37) 120.81(14) C(38)-Fe(2)-C(37) 40.95(13) C(34)-Fe(2)-C(37) 153.64(14) C(39)-Fe(2)-C(37) 68.82(14) C(35)-Fe(2)-C(37) 165.34(13) C(40)-Fe(2)-C(37) 68.34(14) C(33)-Fe(2)-C(32) 40.82(13) C(38)-Fe(2)-C(32) 123.38(14) C(34)-Fe(2)-C(32) 68.62(14) C(39)-Fe(2)-C(32) 157.05(14) C(35)-Fe(2)-C(32) 68.20(13) C(40)-Fe(2)-C(32) 162.06(13) C(37)-Fe(2)-C(32) 110.56(13) C(33)-Fe(2)-C(36) 159.17(14) C(38)-Fe(2)-C(36) 68.40(13) C(34)-Fe(2)-C(36) 159.88(14) C(39)-Fe(2)-C(36) 68.40(13) C(35)-Fe(2)-C(36) 127.67(13) C(40)-Fe(2)-C(36) 40.46(13) C(37)-Fe(2)-C(36) 40.56(13) C(32)-Fe(2)-C(36) 127.05(13) C(33)-Fe(2)-C(31) 68.66(13) C(38)-Fe(2)-C(31) 162.40(14) C(34)-Fe(2)-C(31) 68.73(13) C(39)-Fe(2)-C(31) 156.71(14) C(35)-Fe(2)-C(31) 40.71(12) C(40)-Fe(2)-C(31) 125.30(13) C(37)-Fe(2)-C(31) 128.89(13) C(32)-Fe(2)-C(31) 40.51(12) C(36)-Fe(2)-C(31) 113.58(12) C(43)-Fe(3)-C(42) 40.78(12) C(43)-Fe(3)-C(44) 40.79(13) C(42)-Fe(3)-C(44) 68.34(13) C(43)-Fe(3)-C(46) 119.47(13) C(42)-Fe(3)-C(46) 155.04(13) C(44)-Fe(3)-C(46) 106.75(13) C(43)-Fe(3)-C(47) 103.17(14) C(42)-Fe(3)-C(47) 119.17(13) C(44)-Fe(3)-C(47) 120.47(13)
111
C(46)-Fe(3)-C(47) 40.62(13) C(43)-Fe(3)-C(48) 120.23(14) C(42)-Fe(3)-C(48) 106.15(13) C(44)-Fe(3)-C(48) 156.62(14) C(46)-Fe(3)-C(48) 68.14(13) C(47)-Fe(3)-C(48) 40.78(12) C(43)-Fe(3)-C(49) 158.03(14) C(42)-Fe(3)-C(49) 124.28(13) C(44)-Fe(3)-C(49) 160.93(14) C(46)-Fe(3)-C(49) 68.03(13) C(47)-Fe(3)-C(49) 68.35(13) C(48)-Fe(3)-C(49) 40.37(14) C(43)-Fe(3)-C(50) 157.04(13) C(42)-Fe(3)-C(50) 162.00(13) C(44)-Fe(3)-C(50) 123.80(13) C(46)-Fe(3)-C(50) 40.48(13) C(47)-Fe(3)-C(50) 68.38(13) C(48)-Fe(3)-C(50) 68.07(13) C(49)-Fe(3)-C(50) 40.46(13) C(43)-Fe(3)-C(45) 68.57(13) C(42)-Fe(3)-C(45) 68.45(12) C(44)-Fe(3)-C(45) 40.43(13) C(46)-Fe(3)-C(45) 124.64(12) C(47)-Fe(3)-C(45) 158.26(13) C(48)-Fe(3)-C(45) 160.71(13) C(49)-Fe(3)-C(45) 126.33(13) C(50)-Fe(3)-C(45) 111.05(13) C(43)-Fe(3)-C(41) 68.41(12) C(42)-Fe(3)-C(41) 40.64(12) C(44)-Fe(3)-C(41) 67.95(12) C(46)-Fe(3)-C(41) 162.23(13) C(47)-Fe(3)-C(41) 156.91(12) C(48)-Fe(3)-C(41) 123.56(12) C(49)-Fe(3)-C(41) 111.10(12) C(50)-Fe(3)-C(41) 127.25(13) C(45)-Fe(3)-C(41) 40.48(11) C(54)-Fe(4)-C(53) 40.91(13) C(54)-Fe(4)-C(59) 103.99(15) C(53)-Fe(4)-C(59) 118.41(14) C(54)-Fe(4)-C(58) 117.93(15) C(53)-Fe(4)-C(58) 102.49(14) C(59)-Fe(4)-C(58) 40.71(17) C(54)-Fe(4)-C(52) 68.37(12) C(53)-Fe(4)-C(52) 40.70(12) C(59)-Fe(4)-C(52) 155.47(15) C(58)-Fe(4)-C(52) 120.66(15) C(54)-Fe(4)-C(60) 122.63(14) C(53)-Fe(4)-C(60) 156.12(14) C(59)-Fe(4)-C(60) 40.32(15) C(58)-Fe(4)-C(60) 68.00(15) C(52)-Fe(4)-C(60) 162.87(14) C(54)-Fe(4)-C(57) 154.41(15) C(53)-Fe(4)-C(57) 119.58(15) C(59)-Fe(4)-C(57) 68.45(17) C(58)-Fe(4)-C(57) 40.56(17) C(52)-Fe(4)-C(57) 107.88(15)
C(60)-Fe(4)-C(57) 68.21(15) C(54)-Fe(4)-C(56) 161.14(14) C(53)-Fe(4)-C(56) 157.95(14) C(59)-Fe(4)-C(56) 68.07(16) C(58)-Fe(4)-C(56) 67.96(15) C(52)-Fe(4)-C(56) 125.85(14) C(60)-Fe(4)-C(56) 40.49(15) C(57)-Fe(4)-C(56) 40.47(15) C(54)-Fe(4)-C(55) 40.73(12) C(53)-Fe(4)-C(55) 68.57(13) C(59)-Fe(4)-C(55) 122.20(15) C(58)-Fe(4)-C(55) 155.66(16) C(52)-Fe(4)-C(55) 68.03(12) C(60)-Fe(4)-C(55) 110.67(13) C(57)-Fe(4)-C(55) 163.43(15) C(56)-Fe(4)-C(55) 127.94(14) C(54)-Fe(4)-C(51) 68.07(12) C(53)-Fe(4)-C(51) 68.31(12) C(59)-Fe(4)-C(51) 160.12(15) C(58)-Fe(4)-C(51) 159.17(15) C(52)-Fe(4)-C(51) 40.45(12) C(60)-Fe(4)-C(51) 127.54(13) C(57)-Fe(4)-C(51) 126.49(15) C(56)-Fe(4)-C(51) 113.37(14) C(55)-Fe(4)-C(51) 40.14(11) C(4)-N(1)-C(1) 107.3(3) C(4)-N(1)-In(1A) 121.37(19) C(1)-N(1)-In(1A) 121.51(19) C(4)-N(1)-In(1B) 125.7(2) C(1)-N(1)-In(1B) 126.4(2) In(1A)-N(1)-In(1B) 35.18(5) C(6)-N(2)-C(9) 107.7(2) C(6)-N(2)-In(1A) 124.9(2) C(9)-N(2)-In(1A) 125.66(19) C(6)-N(2)-In(1B) 124.7(2) C(9)-N(2)-In(1B) 120.9(2) In(1A)-N(2)-In(1B) 35.19(5) C(14)-N(3)-C(11) 107.3(2) C(14)-N(3)-In(1B) 116.68(19) C(11)-N(3)-In(1B) 118.36(19) C(14)-N(3)-In(1A) 126.20(19) C(11)-N(3)-In(1A) 126.4(2) In(1B)-N(3)-In(1A) 36.30(6) C(19)-N(4)-C(16) 108.0(2) C(19)-N(4)-In(1A) 124.2(2) C(16)-N(4)-In(1A) 125.27(19) C(19)-N(4)-In(1B) 125.85(19) C(16)-N(4)-In(1B) 120.3(2) In(1A)-N(4)-In(1B) 35.91(5) N(1)-C(1)-C(20) 125.9(3) N(1)-C(1)-C(2) 108.7(3) C(20)-C(1)-C(2) 125.4(3) C(3)-C(2)-C(1) 107.5(3) C(2)-C(3)-C(4) 107.6(3) N(1)-C(4)-C(5) 126.2(3) N(1)-C(4)-C(3) 108.9(3)
112
C(5)-C(4)-C(3) 124.8(3) C(6)-C(5)-C(4) 125.8(3) C(6)-C(5)-C(31) 119.9(3) C(4)-C(5)-C(31) 114.3(3) N(2)-C(6)-C(5) 125.3(3) N(2)-C(6)-C(7) 108.7(3) C(5)-C(6)-C(7) 126.0(3) C(8)-C(7)-C(6) 107.5(3) C(7)-C(8)-C(9) 108.1(3) N(2)-C(9)-C(10) 125.7(3) N(2)-C(9)-C(8) 108.0(3) C(10)-C(9)-C(8) 126.1(3) C(9)-C(10)-C(11) 125.2(3) C(9)-C(10)-C(41) 120.1(3) C(11)-C(10)-C(41) 114.4(3) N(3)-C(11)-C(10) 126.0(3) N(3)-C(11)-C(12) 108.9(2) C(10)-C(11)-C(12) 125.1(3) C(13)-C(12)-C(11) 107.6(3) C(12)-C(13)-C(14) 107.4(3) N(3)-C(14)-C(15) 126.1(3) N(3)-C(14)-C(13) 108.6(2) C(15)-C(14)-C(13) 125.2(3) C(16)-C(15)-C(14) 124.7(3) C(16)-C(15)-C(51) 120.3(3) C(14)-C(15)-C(51) 114.7(3) N(4)-C(16)-C(15) 126.4(3) N(4)-C(16)-C(17) 108.1(3) C(15)-C(16)-C(17) 125.3(3) C(18)-C(17)-C(16) 107.7(3) C(17)-C(18)-C(19) 107.8(3) N(4)-C(19)-C(20) 126.4(3) N(4)-C(19)-C(18) 108.3(3) C(20)-C(19)-C(18) 125.3(3) C(1)-C(20)-C(19) 124.4(3) C(1)-C(20)-C(21) 115.5(3) C(19)-C(20)-C(21) 120.0(3) C(25)-C(21)-C(22) 106.2(3) C(25)-C(21)-C(20) 128.2(3) C(22)-C(21)-C(20) 125.0(3) C(25)-C(21)-Fe(1) 69.15(17) C(22)-C(21)-Fe(1) 67.62(17) C(20)-C(21)-Fe(1) 133.8(2) C(23)-C(22)-C(21) 108.7(3) C(23)-C(22)-Fe(1) 69.67(19) C(21)-C(22)-Fe(1) 71.55(18) C(22)-C(23)-C(24) 108.0(3) C(22)-C(23)-Fe(1) 69.45(19) C(24)-C(23)-Fe(1) 70.57(19) C(25)-C(24)-C(23) 107.8(3) C(25)-C(24)-Fe(1) 70.28(18) C(23)-C(24)-Fe(1) 68.7(2) C(24)-C(25)-C(21) 109.2(3) C(24)-C(25)-Fe(1) 69.69(19) C(21)-C(25)-Fe(1) 70.40(18) C(30)-C(26)-C(27) 107.2(3)
C(30)-C(26)-Fe(1) 69.67(19) C(27)-C(26)-Fe(1) 69.0(2) C(30)-C(26)-H(26) 126.4 C(27)-C(26)-H(26) 126.4 C(28)-C(27)-C(26) 108.4(3) C(28)-C(27)-Fe(1) 69.7(2) C(26)-C(27)-Fe(1) 70.13(19) C(27)-C(28)-C(29) 107.7(3) C(27)-C(28)-Fe(1) 69.60(19) C(29)-C(28)-Fe(1) 69.65(19) C(30)-C(29)-C(28) 107.9(3) C(30)-C(29)-Fe(1) 70.12(18) C(28)-C(29)-Fe(1) 69.48(19) C(29)-C(30)-C(26) 108.8(3) C(29)-C(30)-Fe(1) 69.53(19) C(26)-C(30)-Fe(1) 69.88(18) C(35)-C(31)-C(32) 106.3(3) C(35)-C(31)-C(5) 123.8(3) C(32)-C(31)-C(5) 129.4(3) C(35)-C(31)-Fe(2) 67.85(17) C(32)-C(31)-Fe(2) 68.78(17) C(5)-C(31)-Fe(2) 134.1(2) C(33)-C(32)-C(31) 108.4(3) C(33)-C(32)-Fe(2) 68.52(19) C(31)-C(32)-Fe(2) 70.71(17) C(34)-C(33)-C(32) 108.2(3) C(34)-C(33)-Fe(2) 69.64(19) C(32)-C(33)-Fe(2) 70.66(18) C(35)-C(34)-C(33) 107.7(3) C(35)-C(34)-Fe(2) 69.79(18) C(33)-C(34)-Fe(2) 69.44(19) C(34)-C(35)-C(31) 109.3(3) C(34)-C(35)-Fe(2) 69.51(18) C(31)-C(35)-Fe(2) 71.44(17) C(40)-C(36)-C(37) 107.9(3) C(40)-C(36)-Fe(2) 69.28(18) C(37)-C(36)-Fe(2) 69.26(18) C(36)-C(37)-C(38) 107.5(3) C(36)-C(37)-Fe(2) 70.18(18) C(38)-C(37)-Fe(2) 68.83(18) C(39)-C(38)-C(37) 108.3(3) C(39)-C(38)-Fe(2) 69.66(18) C(37)-C(38)-Fe(2) 70.22(18) C(40)-C(39)-C(38) 107.9(3) C(40)-C(39)-Fe(2) 70.26(18) C(38)-C(39)-Fe(2) 69.46(19) C(39)-C(40)-C(36) 108.4(3) C(39)-C(40)-Fe(2) 69.12(19) C(36)-C(40)-Fe(2) 70.27(18) C(42)-C(41)-C(45) 107.0(3) C(42)-C(41)-C(10) 124.6(3) C(45)-C(41)-C(10) 127.9(3) C(42)-C(41)-Fe(3) 67.82(16) C(45)-C(41)-Fe(3) 68.85(16) C(10)-C(41)-Fe(3) 134.5(2) C(43)-C(42)-C(41) 108.7(3)
113
C(43)-C(42)-Fe(3) 69.47(17) C(41)-C(42)-Fe(3) 71.54(17) C(42)-C(43)-C(44) 107.6(3) C(42)-C(43)-Fe(3) 69.75(18) C(44)-C(43)-Fe(3) 69.85(18) C(45)-C(44)-C(43) 108.8(3) C(45)-C(44)-Fe(3) 70.64(18) C(43)-C(44)-Fe(3) 69.36(19) C(44)-C(45)-C(41) 107.9(3) C(44)-C(45)-Fe(3) 68.93(18) C(41)-C(45)-Fe(3) 70.67(17) C(50)-C(46)-C(47) 108.6(3) C(50)-C(46)-Fe(3) 70.15(17) C(47)-C(46)-Fe(3) 69.85(18) C(46)-C(47)-C(48) 107.3(3) C(46)-C(47)-Fe(3) 69.54(18) C(48)-C(47)-Fe(3) 69.80(18) C(49)-C(48)-C(47) 108.1(3) C(49)-C(48)-Fe(3) 69.82(18) C(47)-C(48)-Fe(3) 69.41(18) C(48)-C(49)-C(50) 108.2(3) C(48)-C(49)-Fe(3) 69.81(19) C(50)-C(49)-Fe(3) 69.81(18) C(46)-C(50)-C(49) 107.7(3) C(46)-C(50)-Fe(3) 69.37(18) C(49)-C(50)-Fe(3) 69.73(18) C(55)-C(51)-C(52) 106.7(3) C(55)-C(51)-C(15) 127.2(3) C(52)-C(51)-C(15) 125.4(3) C(55)-C(51)-Fe(4) 68.31(16) C(52)-C(51)-Fe(4) 67.78(16) C(15)-C(51)-Fe(4) 136.2(2) C(53)-C(52)-C(51) 108.9(3) C(53)-C(52)-Fe(4) 69.26(17) C(51)-C(52)-Fe(4) 71.77(17) C(52)-C(53)-C(54) 107.5(3) C(52)-C(53)-Fe(4) 70.04(18) C(54)-C(53)-Fe(4) 69.33(18) C(53)-C(54)-C(55) 108.3(3) C(53)-C(54)-Fe(4) 69.76(18) C(55)-C(54)-Fe(4) 70.62(17) C(54)-C(55)-C(51) 108.5(3) C(54)-C(55)-Fe(4) 68.65(17) C(51)-C(55)-Fe(4) 71.55(17) C(60)-C(56)-C(57) 108.2(3) C(60)-C(56)-Fe(4) 69.55(19) C(57)-C(56)-Fe(4) 69.7(2) C(58)-C(57)-C(56) 107.4(4) C(58)-C(57)-Fe(4) 69.3(2) C(56)-C(57)-Fe(4) 69.8(2) C(57)-C(58)-C(59) 108.3(3) C(57)-C(58)-Fe(4) 70.1(2) C(59)-C(58)-Fe(4) 69.5(2) C(60)-C(59)-C(58) 107.9(4) C(60)-C(59)-Fe(4) 70.14(19) C(58)-C(59)-Fe(4) 69.7(2)
C(59)-C(60)-C(56) 108.2(3) C(59)-C(60)-Fe(4) 69.5(2) C(56)-C(60)-Fe(4) 70.0(2)
114
______________________________________________________________________________ Anisotropic displacement parameters (A^2 x 10^3)
The anisotropic displacement factor exponent takes the form:
-2 pi^2 [ h^2 a*^2 U11 + ... + 2 h k a* b* U12 ]
_______________________________________________________________________ U11 U22 U33 U23 U13 U12 _______________________________________________________________________
In(1A) 21(1) 16(1) 29(1) 1(1) -5(1) -6(1) Cl(1A) 39(1) 37(1) 35(1) -3(1) -14(1) -2(1) C(61) 65(4) 100(5) 62(4) 3(4) -4(3) -9(4) C(62) 88(5) 86(5) 108(6) 26(4) -25(5) -26(4) C(63) 97(6) 88(5) 95(6) 20(4) -31(5) -25(5) C(64) 74(4) 91(5) 83(5) 30(4) -30(4) -31(4) C(65) 61(4) 89(5) 55(3) 19(3) -17(3) -14(3) C(66) 54(3) 85(5) 55(3) 24(3) -25(3) -23(3) C(67) 82(4) 90(5) 64(4) 14(3) -24(3) -35(4) In(1B) 22(1) 17(1) 33(1) -1(1) -5(1) -5(1) Cl(1B) 56(4) 55(4) 50(4) -8(3) -26(3) 12(3) Fe(1) 26(1) 19(1) 34(1) -5(1) -5(1) -5(1) Fe(2) 23(1) 25(1) 28(1) -6(1) 0(1) -9(1) Fe(3) 28(1) 17(1) 28(1) -3(1) -5(1) -6(1) Fe(4) 27(1) 24(1) 29(1) -3(1) -3(1) -10(1) N(1) 23(1) 18(1) 38(1) 1(1) -7(1) -7(1) N(2) 22(1) 18(1) 46(2) -2(1) -4(1) -6(1) N(3) 23(1) 18(1) 37(1) -1(1) -4(1) -6(1) N(4) 22(1) 19(1) 37(1) 1(1) -3(1) -6(1) C(1) 26(1) 23(1) 31(2) -1(1) -8(1) -6(1) C(2) 42(2) 26(2) 31(2) -6(1) 0(1) -15(1) C(3) 38(2) 30(2) 29(2) -4(1) -1(1) -14(1) C(4) 25(1) 25(2) 32(2) -1(1) -6(1) -9(1) C(5) 25(1) 21(1) 32(2) 1(1) -7(1) -9(1) C(6) 22(1) 23(1) 38(2) 1(1) -7(1) -7(1) C(7) 26(2) 22(1) 41(2) 3(1) -6(1) -11(1) C(8) 26(2) 18(1) 44(2) 0(1) -9(1) -8(1) C(9) 22(1) 18(1) 44(2) -2(1) -8(1) -5(1) C(10) 25(1) 17(1) 37(2) 0(1) -10(1) -6(1) C(11) 26(1) 20(1) 32(2) 1(1) -9(1) -6(1) C(12) 32(2) 21(1) 30(2) -1(1) -9(1) -8(1) C(13) 30(2) 22(1) 28(2) 1(1) -7(1) -8(1) C(14) 24(1) 20(1) 32(2) 2(1) -6(1) -7(1) C(15) 25(1) 19(1) 33(2) 3(1) -9(1) -7(1) C(16) 25(1) 18(1) 36(2) 2(1) -7(1) -7(1) C(17) 28(2) 18(1) 41(2) 1(1) -5(1) -7(1) C(18) 28(2) 17(1) 43(2) -2(1) -5(1) -7(1) C(19) 25(1) 18(1) 37(2) 2(1) -8(1) -6(1) C(20) 25(1) 20(1) 34(2) -1(1) -8(1) -7(1) C(21) 30(2) 22(1) 33(2) -2(1) -4(1) -7(1) C(22) 28(2) 24(2) 46(2) -4(1) -1(1) -9(1) C(23) 35(2) 29(2) 43(2) -8(1) 5(1) -6(1)
115
C(24) 43(2) 28(2) 33(2) -7(1) -3(1) -8(1) C(25) 34(2) 23(1) 32(2) -1(1) -9(1) -8(1) C(26) 38(2) 25(2) 35(2) -2(1) -3(1) -5(1) C(27) 44(2) 27(2) 35(2) -6(1) -9(1) -5(1) C(28) 41(2) 30(2) 44(2) -7(1) -19(2) -4(1) C(29) 35(2) 26(2) 49(2) -4(1) -17(2) 1(1) C(30) 38(2) 20(1) 43(2) -3(1) -8(1) -7(1) C(31) 28(2) 26(2) 28(2) -5(1) -4(1) -9(1) C(32) 38(2) 29(2) 28(2) -3(1) -5(1) -14(1) C(33) 42(2) 41(2) 28(2) -12(1) 7(1) -20(2) C(34) 33(2) 36(2) 40(2) -17(1) 6(1) -13(1) C(35) 28(2) 24(2) 38(2) -8(1) 1(1) -9(1) C(36) 31(2) 36(2) 28(2) -12(1) 1(1) -10(1) C(37) 37(2) 27(2) 37(2) -8(1) -6(1) -9(1) C(38) 36(2) 35(2) 37(2) -10(1) 1(1) -20(1) C(39) 28(2) 39(2) 46(2) -12(2) -6(1) -12(1) C(40) 39(2) 35(2) 32(2) -4(1) -10(1) -13(1) C(41) 30(2) 19(1) 31(2) -1(1) -6(1) -9(1) C(42) 30(2) 19(1) 37(2) -3(1) -3(1) -9(1) C(43) 35(2) 24(2) 35(2) -5(1) 4(1) -7(1) C(44) 47(2) 25(2) 28(2) -2(1) -5(1) -12(1) C(45) 36(2) 23(1) 32(2) 1(1) -11(1) -12(1) C(46) 40(2) 20(1) 33(2) -1(1) -6(1) -8(1) C(47) 37(2) 22(2) 37(2) -2(1) -11(1) -3(1) C(48) 43(2) 23(2) 34(2) -1(1) -16(1) -5(1) C(49) 47(2) 23(2) 26(2) -3(1) -5(1) -6(1) C(50) 35(2) 25(2) 33(2) 3(1) -4(1) -10(1) C(51) 29(2) 19(1) 31(2) -1(1) -6(1) -9(1) C(52) 29(2) 20(1) 35(2) -1(1) -3(1) -8(1) C(53) 31(2) 26(2) 34(2) -5(1) -1(1) -10(1) C(54) 38(2) 26(2) 27(2) -2(1) -3(1) -11(1) C(55) 34(2) 18(1) 28(2) -1(1) -7(1) -8(1) C(56) 43(2) 46(2) 34(2) -14(2) -6(2) -13(2) C(57) 46(2) 49(2) 45(2) -14(2) -21(2) -7(2) C(58) 32(2) 54(2) 67(3) -28(2) -4(2) -17(2) C(59) 54(2) 39(2) 53(2) -14(2) 1(2) -30(2) C(60) 42(2) 30(2) 47(2) -15(2) -6(2) -11(1) _______________________________________________________________________
CIF Information for Compound 8:
Empirical formula C70 H53 Fe5 In N4 Formula weight 1344.23 Temperature 123(2) K Wavelength 0.71073 A Crystal system, space group Triclinic, P-1 Unit cell dimensions a = 13.709 A alpha = 69.95 deg. b = 14.553 A beta = 76.12 deg. c = 15.818 A gamma = 63.42 deg. Volume 2637.3 A^3 Z, Calculated density 2, 1.693 Mg/m^3 Absorption coefficient 1.820 mm^-1 F(000) 1360 Crystal size 0.30 x 0.04 x 0.04 mm
116
Theta range for data collection 3.00 to 25.04 deg. Limiting indices -15<=h<=16, -17<=k<=17, -18<=l<=18 Reflections collected / unique 26966 / 9252 [R(int) = 0.0879] Completeness to theta = 25.04 99.0 % Absorption correction Empirical Max. and min. transmission 0.9308 and 0.6113 Refinement method Full-matrix least-squares on F^2 Data / restraints / parameters 9252 / 0 / 721 Goodness-of-fit on F^2 1.010 Final R indices [I>2sigma(I)] R1 = 0.0549, wR2 = 0.1274 R indices (all data) R1 = 0.0810, wR2 = 0.1435 Largest diff. peak and hole 1.171 and -0.953 e.A^-3
Atomic coordinates ( x 10^4) and equivalent isotropic displacement parameters (A^2 x 10^3)
U(eq) is defined as one third of the trace of the orthogonalized Uij tensor.
______________________________________________________________________________ x y z U(eq) x y z U(eq) ______________________________________________________________________________
In(1) 5095(1) 6993(1) 286(1) 23(1) Fe(1) 8123(1) 7048(1) 2771(1) 31(1) Fe(2) 2406(1) 6490(1) 4187(1) 34(1) Fe(3) 1619(1) 8007(1) -2307(1) 26(1) Fe(4) 7335(1) 8513(1) -3637(1) 29(1) Fe(5) 2675(1) 9616(1) 323(1) 41(1) N(1) 6865(4) 6556(4) -38(3) 24(1) N(2) 5543(4) 6106(3) 1684(3) 23(1) N(3) 3947(3) 6220(4) 680(3) 22(1) N(4) 5226(3) 6736(4) -1044(3) 22(1) C(1) 7425(4) 6600(4) -882(4) 26(1) C(2) 8579(4) 6243(5) -798(4) 28(1) C(3) 8676(4) 6065(4) 71(4) 27(1) C(4) 7608(4) 6279(4) 563(4) 24(1) C(5) 7350(4) 6192(4) 1501(4) 22(1) C(6) 6398(4) 6090(4) 2017(4) 27(1) C(7) 6186(4) 5844(4) 2988(4) 27(1) C(8) 5222(4) 5729(5) 3221(4) 29(1) C(9) 4814(4) 5899(4) 2405(4) 25(1) C(10) 3833(4) 5838(4) 2340(4) 26(1) C(11) 3506(4) 5889(4) 1542(4) 23(1) C(12) 2632(4) 5603(4) 1500(4) 25(1) C(13) 2543(4) 5800(4) 624(4) 25(1) C(14) 3331(4) 6226(4) 90(4) 24(1) C(15) 3449(4) 6583(4) -861(4) 23(1) C(16) 4368(4) 6760(4) -1380(4) 24(1) C(17) 4595(5) 6970(5) -2346(4) 28(1) C(18) 5563(4) 7074(5) -2586(4) 28(1) C(19) 5955(4) 6935(4) -1769(4) 24(1)
C(20) 6981(4) 6912(4) -1702(4) 25(1) C(21) 8215(4) 6172(4) 1942(4) 26(1) C(22) 8828(5) 6826(5) 1532(4) 33(1) C(23) 9644(5) 6531(6) 2089(5) 41(2) C(24) 9549(5) 5693(5) 2853(5) 39(2) C(25) 8682(5) 5477(5) 2766(4) 31(1) C(26) 8058(6) 8229(5) 3226(5) 49(2) C(27) 7316(7) 8666(5) 2549(5) 54(2) C(28) 6558(6) 8192(6) 2868(5) 52(2) C(29) 6808(6) 7479(6) 3715(5) 49(2) C(30) 7720(7) 7497(6) 3952(5) 51(2) C(31) 3043(5) 5702(5) 3171(4) 30(1) C(32) 3242(5) 4961(5) 4041(4) 35(1) C(33) 2223(6) 5079(6) 4577(4) 46(2) C(34) 1375(6) 5893(7) 4048(5) 47(2) C(35) 1886(5) 6283(5) 3188(4) 35(2) C(36) 1412(7) 7705(10) 4727(9) 89(4) C(37) 1991(7) 8091(6) 3906(6) 63(2) C(38) 3087(6) 7549(6) 4005(5) 51(2) C(39) 3234(8) 6885(7) 4826(7) 66(2) C(40) 2237(13) 6963(9) 5305(5) 99(4) C(41) 2523(4) 6746(4) -1292(4) 22(1) C(42) 2519(4) 6384(4) -2035(4) 26(1) C(43) 1404(5) 6645(4) -2131(4) 28(1) C(44) 711(5) 7180(5) -1478(4) 31(1) C(45) 1382(4) 7258(5) -966(4) 27(1) C(46) 1249(5) 8950(5) -3584(4) 40(2) C(47) 512(5) 9461(5) -2936(5) 42(2) C(48) 1109(5) 9597(5) -2400(4) 38(2)
117
C(49) 2239(5) 9149(5) -2731(4) 38(2) C(50) 2317(5) 8755(5) -3462(4) 37(2) C(51) 7696(4) 7197(5) -2533(4) 28(1) C(52) 8290(4) 7820(5) -2607(4) 28(1) C(53) 8960(5) 7870(5) -3445(4) 38(2) C(54) 8770(5) 7300(5) -3907(4) 34(1) C(55) 8003(5) 6881(5) -3351(4) 29(1) C(56) 6797(6) 9550(5) -4854(5) 47(2) C(57) 5996(6) 9162(5) -4331(5) 49(2) C(58) 5688(6) 9452(5) -3511(5) 45(2) C(59) 6293(6) 10015(5) -3515(5) 48(2)
C(60) 6990(6) 10076(5) -4333(5) 49(2) C(61) 4336(5) 8659(5) 246(5) 37(2) C(62) 3987(6) 9100(6) 1011(6) 55(2) C(63) 3508(7) 10240(6) 705(8) 73(3) C(64) 3588(6) 10507(6) -249(7) 61(2) C(65) 4085(5) 9542(5) -522(6) 49(2) C(66) 1432(6) 9359(8) 1206(6) 71(3) C(67) 1046(6) 10411(7) 640(7) 68(3) C(68) 1230(6) 10341(6) -251(6) 59(2) C(69) 1727(6) 9250(6) -232(6) 53(2) C(70) 1819(5) 8659(6) 665(5) 47(2)
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Bond lengths [A] and angles [deg]
______________________________________________________________________________
In(1)-C(61) 2.152(6) In(1)-N(3) 2.183(4) In(1)-N(1) 2.191(4) In(1)-N(4) 2.213(4) In(1)-N(2) 2.218(4) Fe(1)-C(22) 2.030(6) Fe(1)-C(23) 2.036(7) Fe(1)-C(26) 2.040(6) Fe(1)-C(27) 2.045(7) Fe(1)-C(29) 2.053(7) Fe(1)-C(28) 2.055(7) Fe(1)-C(24) 2.055(6) Fe(1)-C(30) 2.060(6) Fe(1)-C(25) 2.063(6) Fe(1)-C(21) 2.069(5) Fe(2)-C(36) 2.009(8) Fe(2)-C(35) 2.037(6) Fe(2)-C(40) 2.038(7) Fe(2)-C(33) 2.043(7) Fe(2)-C(34) 2.043(6) Fe(2)-C(37) 2.044(7) Fe(2)-C(39) 2.044(7) Fe(2)-C(38) 2.047(7) Fe(2)-C(32) 2.064(6) Fe(2)-C(31) 2.086(6) Fe(3)-C(49) 2.040(6) Fe(3)-C(50) 2.041(6) Fe(3)-C(47) 2.044(6) Fe(3)-C(46) 2.046(6) Fe(3)-C(45) 2.048(6) Fe(3)-C(44) 2.048(6) Fe(3)-C(43) 2.049(6) Fe(3)-C(48) 2.058(6) Fe(3)-C(42) 2.059(6) Fe(3)-C(41) 2.093(5) Fe(4)-C(52) 2.026(6) Fe(4)-C(57) 2.041(7) Fe(4)-C(54) 2.044(6)
Fe(4)-C(60) 2.045(7) Fe(4)-C(53) 2.049(6) Fe(4)-C(55) 2.050(6) Fe(4)-C(58) 2.053(7) Fe(4)-C(59) 2.054(7) Fe(4)-C(56) 2.054(7) Fe(4)-C(51) 2.059(6) Fe(5)-C(66) 2.015(9) Fe(5)-C(67) 2.031(7) Fe(5)-C(63) 2.033(8) Fe(5)-C(62) 2.039(7) Fe(5)-C(64) 2.043(8) Fe(5)-C(68) 2.048(7) Fe(5)-C(65) 2.051(7) Fe(5)-C(69) 2.056(7) Fe(5)-C(70) 2.062(7) Fe(5)-C(61) 2.070(6) N(1)-C(1) 1.368(7) N(1)-C(4) 1.392(7) N(2)-C(9) 1.370(7) N(2)-C(6) 1.384(7) N(3)-C(11) 1.367(7) N(3)-C(14) 1.397(7) N(4)-C(19) 1.371(7) N(4)-C(16) 1.384(6) C(1)-C(20) 1.410(8) C(1)-C(2) 1.452(7) C(2)-C(3) 1.337(8) C(3)-C(4) 1.434(8) C(4)-C(5) 1.415(8) C(5)-C(6) 1.405(8) C(5)-C(21) 1.498(7) C(6)-C(7) 1.440(8) C(7)-C(8) 1.354(8) C(8)-C(9) 1.430(7) C(9)-C(10) 1.414(7) C(10)-C(11) 1.408(7) C(10)-C(31) 1.507(8)
118
C(11)-C(12) 1.455(7) C(12)-C(13) 1.339(8) C(13)-C(14) 1.439(8) C(14)-C(15) 1.408(8) C(15)-C(16) 1.406(8) C(15)-C(41) 1.472(7) C(16)-C(17) 1.436(8) C(17)-C(18) 1.351(8) C(18)-C(19) 1.434(7) C(19)-C(20) 1.419(7) C(20)-C(51) 1.494(8) C(21)-C(25) 1.432(8) C(21)-C(22) 1.436(8) C(22)-C(23) 1.413(8) C(23)-C(24) 1.421(10) C(24)-C(25) 1.405(8) C(26)-C(30) 1.421(10) C(26)-C(27) 1.436(10) C(27)-C(28) 1.402(11) C(28)-C(29) 1.392(11) C(29)-C(30) 1.402(10) C(31)-C(35) 1.424(8) C(31)-C(32) 1.424(8) C(32)-C(33) 1.420(9) C(33)-C(34) 1.418(10) C(34)-C(35) 1.425(9) C(36)-C(40) 1.417(15) C(36)-C(37) 1.427(14) C(37)-C(38) 1.368(10) C(38)-C(39) 1.324(11) C(39)-C(40) 1.371(14) C(41)-C(42) 1.444(7) C(41)-C(45) 1.450(7) C(42)-C(43) 1.433(7) C(43)-C(44) 1.412(8) C(44)-C(45) 1.424(8) C(46)-C(47) 1.405(9) C(46)-C(50) 1.409(9) C(47)-C(48) 1.422(9) C(48)-C(49) 1.429(9) C(49)-C(50) 1.420(9) C(51)-C(55) 1.428(8) C(51)-C(52) 1.429(8) C(52)-C(53) 1.419(8) C(53)-C(54) 1.412(8) C(54)-C(55) 1.419(8) C(56)-C(57) 1.416(10) C(56)-C(60) 1.433(9) C(57)-C(58) 1.411(10) C(58)-C(59) 1.399(10) C(59)-C(60) 1.415(10) C(61)-C(65) 1.407(10) C(61)-C(62) 1.444(10) C(62)-C(63) 1.430(11) C(63)-C(64) 1.413(13) C(64)-C(65) 1.430(10)
C(66)-C(70) 1.397(11) C(66)-C(67) 1.410(13) C(67)-C(68) 1.402(12) C(68)-C(69) 1.412(10) C(69)-C(70) 1.387(10) C(61)-In(1)-N(3) 113.85(19) C(61)-In(1)-N(1) 107.65(19) N(3)-In(1)-N(1) 138.43(16) C(61)-In(1)-N(4) 112.3(2) N(3)-In(1)-N(4) 83.41(16) N(1)-In(1)-N(4) 83.23(15) C(61)-In(1)-N(2) 106.3(2) N(3)-In(1)-N(2) 82.97(16) N(1)-In(1)-N(2) 83.41(16) N(4)-In(1)-N(2) 141.35(16) C(22)-Fe(1)-C(23) 40.7(2) C(22)-Fe(1)-C(26) 124.1(3) C(23)-Fe(1)-C(26) 104.8(3) C(22)-Fe(1)-C(27) 104.9(3) C(23)-Fe(1)-C(27) 115.6(3) C(26)-Fe(1)-C(27) 41.2(3) C(22)-Fe(1)-C(29) 153.5(3) C(23)-Fe(1)-C(29) 165.8(3) C(26)-Fe(1)-C(29) 67.6(3) C(27)-Fe(1)-C(29) 67.2(3) C(22)-Fe(1)-C(28) 118.2(3) C(23)-Fe(1)-C(28) 150.4(3) C(26)-Fe(1)-C(28) 68.0(3) C(27)-Fe(1)-C(28) 40.0(3) C(29)-Fe(1)-C(28) 39.6(3) C(22)-Fe(1)-C(24) 68.1(3) C(23)-Fe(1)-C(24) 40.7(3) C(26)-Fe(1)-C(24) 117.9(3) C(27)-Fe(1)-C(24) 151.0(3) C(29)-Fe(1)-C(24) 131.0(3) C(28)-Fe(1)-C(24) 168.2(3) C(22)-Fe(1)-C(30) 162.9(3) C(23)-Fe(1)-C(30) 126.7(3) C(26)-Fe(1)-C(30) 40.6(3) C(27)-Fe(1)-C(30) 68.1(3) C(29)-Fe(1)-C(30) 39.9(3) C(28)-Fe(1)-C(30) 67.2(3) C(24)-Fe(1)-C(30) 109.9(3) C(22)-Fe(1)-C(25) 68.0(2) C(23)-Fe(1)-C(25) 67.9(3) C(26)-Fe(1)-C(25) 153.3(3) C(27)-Fe(1)-C(25) 165.5(3) C(29)-Fe(1)-C(25) 113.1(3) C(28)-Fe(1)-C(25) 130.9(3) C(24)-Fe(1)-C(25) 39.9(2) C(30)-Fe(1)-C(25) 122.2(3) C(22)-Fe(1)-C(21) 41.0(2) C(23)-Fe(1)-C(21) 68.8(2) C(26)-Fe(1)-C(21) 162.9(3) C(27)-Fe(1)-C(21) 126.0(3) C(29)-Fe(1)-C(21) 121.9(2)
119
C(28)-Fe(1)-C(21) 109.4(3) C(24)-Fe(1)-C(21) 68.2(2) C(30)-Fe(1)-C(21) 155.5(3) C(25)-Fe(1)-C(21) 40.6(2) C(36)-Fe(2)-C(35) 118.7(4) C(36)-Fe(2)-C(40) 41.0(4) C(35)-Fe(2)-C(40) 156.1(5) C(36)-Fe(2)-C(33) 122.3(4) C(35)-Fe(2)-C(33) 68.2(3) C(40)-Fe(2)-C(33) 109.2(3) C(36)-Fe(2)-C(34) 104.0(3) C(35)-Fe(2)-C(34) 40.9(2) C(40)-Fe(2)-C(34) 121.4(4) C(33)-Fe(2)-C(34) 40.6(3) C(36)-Fe(2)-C(37) 41.2(4) C(35)-Fe(2)-C(37) 106.5(3) C(40)-Fe(2)-C(37) 67.0(4) C(33)-Fe(2)-C(37) 159.3(3) C(34)-Fe(2)-C(37) 122.4(3) C(36)-Fe(2)-C(39) 67.6(4) C(35)-Fe(2)-C(39) 160.9(4) C(40)-Fe(2)-C(39) 39.2(4) C(33)-Fe(2)-C(39) 125.6(3) C(34)-Fe(2)-C(39) 158.2(4) C(37)-Fe(2)-C(39) 65.3(3) C(36)-Fe(2)-C(38) 67.5(3) C(35)-Fe(2)-C(38) 125.2(3) C(40)-Fe(2)-C(38) 65.3(4) C(33)-Fe(2)-C(38) 159.7(3) C(34)-Fe(2)-C(38) 159.4(3) C(37)-Fe(2)-C(38) 39.1(3) C(39)-Fe(2)-C(38) 37.8(3) C(36)-Fe(2)-C(32) 160.7(4) C(35)-Fe(2)-C(32) 67.6(3) C(40)-Fe(2)-C(32) 126.9(4) C(33)-Fe(2)-C(32) 40.4(3) C(34)-Fe(2)-C(32) 68.0(3) C(37)-Fe(2)-C(32) 157.9(3) C(39)-Fe(2)-C(32) 113.0(3) C(38)-Fe(2)-C(32) 125.7(3) C(36)-Fe(2)-C(31) 155.2(4) C(35)-Fe(2)-C(31) 40.4(2) C(40)-Fe(2)-C(31) 162.8(5) C(33)-Fe(2)-C(31) 68.2(2) C(34)-Fe(2)-C(31) 68.5(2) C(37)-Fe(2)-C(31) 121.6(3) C(39)-Fe(2)-C(31) 127.4(3) C(38)-Fe(2)-C(31) 110.9(3) C(32)-Fe(2)-C(31) 40.1(2) C(49)-Fe(3)-C(50) 40.7(3) C(49)-Fe(3)-C(47) 68.0(3) C(50)-Fe(3)-C(47) 67.8(3) C(49)-Fe(3)-C(46) 68.1(3) C(50)-Fe(3)-C(46) 40.3(2) C(47)-Fe(3)-C(46) 40.2(3) C(49)-Fe(3)-C(45) 122.1(2)
C(50)-Fe(3)-C(45) 158.6(2) C(47)-Fe(3)-C(45) 122.9(3) C(46)-Fe(3)-C(45) 159.1(2) C(49)-Fe(3)-C(44) 156.5(3) C(50)-Fe(3)-C(44) 160.0(2) C(47)-Fe(3)-C(44) 105.8(3) C(46)-Fe(3)-C(44) 122.8(2) C(45)-Fe(3)-C(44) 40.7(2) C(49)-Fe(3)-C(43) 162.5(3) C(50)-Fe(3)-C(43) 125.1(2) C(47)-Fe(3)-C(43) 120.3(2) C(46)-Fe(3)-C(43) 107.4(2) C(45)-Fe(3)-C(43) 68.1(2) C(44)-Fe(3)-C(43) 40.3(2) C(49)-Fe(3)-C(48) 40.8(3) C(50)-Fe(3)-C(48) 68.5(3) C(47)-Fe(3)-C(48) 40.6(3) C(46)-Fe(3)-C(48) 68.3(3) C(45)-Fe(3)-C(48) 106.7(2) C(44)-Fe(3)-C(48) 119.8(3) C(43)-Fe(3)-C(48) 155.0(2) C(49)-Fe(3)-C(42) 126.0(2) C(50)-Fe(3)-C(42) 109.3(2) C(47)-Fe(3)-C(42) 156.6(2) C(46)-Fe(3)-C(42) 122.4(2) C(45)-Fe(3)-C(42) 68.5(2) C(44)-Fe(3)-C(42) 68.5(2) C(43)-Fe(3)-C(42) 40.9(2) C(48)-Fe(3)-C(42) 162.1(2) C(49)-Fe(3)-C(41) 108.9(2) C(50)-Fe(3)-C(41) 123.4(2) C(47)-Fe(3)-C(41) 160.5(2) C(46)-Fe(3)-C(41) 158.4(2) C(45)-Fe(3)-C(41) 41.0(2) C(44)-Fe(3)-C(41) 68.8(2) C(43)-Fe(3)-C(41) 68.6(2) C(48)-Fe(3)-C(41) 124.5(2) C(42)-Fe(3)-C(41) 40.7(2) C(52)-Fe(4)-C(57) 161.3(3) C(52)-Fe(4)-C(54) 68.2(2) C(57)-Fe(4)-C(54) 124.0(3) C(52)-Fe(4)-C(60) 119.5(3) C(57)-Fe(4)-C(60) 68.2(3) C(54)-Fe(4)-C(60) 122.4(3) C(52)-Fe(4)-C(53) 40.8(2) C(57)-Fe(4)-C(53) 157.6(3) C(54)-Fe(4)-C(53) 40.4(2) C(60)-Fe(4)-C(53) 105.0(3) C(52)-Fe(4)-C(55) 68.2(2) C(57)-Fe(4)-C(55) 110.8(3) C(54)-Fe(4)-C(55) 40.6(2) C(60)-Fe(4)-C(55) 160.2(3) C(53)-Fe(4)-C(55) 68.1(2) C(52)-Fe(4)-C(58) 123.8(3) C(57)-Fe(4)-C(58) 40.3(3) C(54)-Fe(4)-C(58) 160.3(3)
120
C(60)-Fe(4)-C(58) 67.9(3) C(53)-Fe(4)-C(58) 158.7(3) C(55)-Fe(4)-C(58) 125.1(3) C(52)-Fe(4)-C(59) 106.5(3) C(57)-Fe(4)-C(59) 67.4(3) C(54)-Fe(4)-C(59) 158.3(3) C(60)-Fe(4)-C(59) 40.4(3) C(53)-Fe(4)-C(59) 121.9(3) C(55)-Fe(4)-C(59) 159.0(3) C(58)-Fe(4)-C(59) 39.8(3) C(52)-Fe(4)-C(56) 155.7(3) C(57)-Fe(4)-C(56) 40.5(3) C(54)-Fe(4)-C(56) 107.7(3) C(60)-Fe(4)-C(56) 40.9(3) C(53)-Fe(4)-C(56) 120.5(3) C(55)-Fe(4)-C(56) 125.3(2) C(58)-Fe(4)-C(56) 68.0(3) C(59)-Fe(4)-C(56) 68.0(3) C(52)-Fe(4)-C(51) 40.9(2) C(57)-Fe(4)-C(51) 126.0(3) C(54)-Fe(4)-C(51) 68.7(2) C(60)-Fe(4)-C(51) 156.1(2) C(53)-Fe(4)-C(51) 68.9(2) C(55)-Fe(4)-C(51) 40.7(2) C(58)-Fe(4)-C(51) 109.1(2) C(59)-Fe(4)-C(51) 122.0(3) C(56)-Fe(4)-C(51) 162.0(2) C(66)-Fe(5)-C(67) 40.8(4) C(66)-Fe(5)-C(63) 116.5(4) C(67)-Fe(5)-C(63) 108.4(3) C(66)-Fe(5)-C(62) 108.9(4) C(67)-Fe(5)-C(62) 131.1(3) C(63)-Fe(5)-C(62) 41.1(3) C(66)-Fe(5)-C(64) 149.6(4) C(67)-Fe(5)-C(64) 117.2(3) C(63)-Fe(5)-C(64) 40.6(4) C(62)-Fe(5)-C(64) 67.8(4) C(66)-Fe(5)-C(68) 67.7(4) C(67)-Fe(5)-C(68) 40.2(3) C(63)-Fe(5)-C(68) 130.8(3) C(62)-Fe(5)-C(68) 169.9(3) C(64)-Fe(5)-C(68) 109.9(3) C(66)-Fe(5)-C(65) 168.2(3) C(67)-Fe(5)-C(65) 149.9(4) C(63)-Fe(5)-C(65) 68.8(4) C(62)-Fe(5)-C(65) 67.5(3) C(64)-Fe(5)-C(65) 40.9(3) C(68)-Fe(5)-C(65) 117.8(3) C(66)-Fe(5)-C(69) 67.5(3) C(67)-Fe(5)-C(69) 67.8(3) C(63)-Fe(5)-C(69) 169.6(3) C(62)-Fe(5)-C(69) 148.5(3) C(64)-Fe(5)-C(69) 131.5(4) C(68)-Fe(5)-C(69) 40.2(3) C(65)-Fe(5)-C(69) 109.3(3) C(66)-Fe(5)-C(70) 40.0(3)
C(67)-Fe(5)-C(70) 67.4(3) C(63)-Fe(5)-C(70) 149.4(4) C(62)-Fe(5)-C(70) 117.4(3) C(64)-Fe(5)-C(70) 169.2(3) C(68)-Fe(5)-C(70) 66.7(3) C(65)-Fe(5)-C(70) 130.5(3) C(69)-Fe(5)-C(70) 39.4(3) C(66)-Fe(5)-C(61) 130.1(3) C(67)-Fe(5)-C(61) 169.6(4) C(63)-Fe(5)-C(61) 69.9(3) C(62)-Fe(5)-C(61) 41.1(3) C(64)-Fe(5)-C(61) 68.6(3) C(68)-Fe(5)-C(61) 148.3(3) C(65)-Fe(5)-C(61) 39.9(3) C(69)-Fe(5)-C(61) 115.7(3) C(70)-Fe(5)-C(61) 108.5(3) C(1)-N(1)-C(4) 107.3(4) C(1)-N(1)-In(1) 126.1(3) C(4)-N(1)-In(1) 126.3(4) C(9)-N(2)-C(6) 107.9(4) C(9)-N(2)-In(1) 123.9(3) C(6)-N(2)-In(1) 123.2(4) C(11)-N(3)-C(14) 107.3(4) C(11)-N(3)-In(1) 126.0(3) C(14)-N(3)-In(1) 124.9(4) C(19)-N(4)-C(16) 107.3(4) C(19)-N(4)-In(1) 124.6(3) C(16)-N(4)-In(1) 123.9(3) N(1)-C(1)-C(20) 126.7(5) N(1)-C(1)-C(2) 108.5(5) C(20)-C(1)-C(2) 124.8(5) C(3)-C(2)-C(1) 107.4(5) C(3)-C(2)-H(2) 126.3 C(1)-C(2)-H(2) 126.3 C(2)-C(3)-C(4) 108.3(5) C(2)-C(3)-H(3) 125.8 C(4)-C(3)-H(3) 125.8 N(1)-C(4)-C(5) 125.5(5) N(1)-C(4)-C(3) 108.1(5) C(5)-C(4)-C(3) 126.3(5) C(6)-C(5)-C(4) 125.1(5) C(6)-C(5)-C(21) 120.4(5) C(4)-C(5)-C(21) 114.4(5) N(2)-C(6)-C(5) 125.5(5) N(2)-C(6)-C(7) 107.8(5) C(5)-C(6)-C(7) 126.4(5) C(8)-C(7)-C(6) 107.9(5) C(7)-C(8)-C(9) 107.5(5) N(2)-C(9)-C(10) 124.9(5) N(2)-C(9)-C(8) 108.9(5) C(10)-C(9)-C(8) 126.2(5) C(11)-C(10)-C(9) 125.3(5) C(11)-C(10)-C(31) 114.5(5) C(9)-C(10)-C(31) 120.2(5) N(3)-C(11)-C(10) 125.9(5) N(3)-C(11)-C(12) 108.8(4)
121
C(10)-C(11)-C(12) 125.3(5) C(13)-C(12)-C(11) 107.3(5) C(12)-C(13)-C(14) 108.4(5) N(3)-C(14)-C(15) 126.7(5) N(3)-C(14)-C(13) 108.0(5) C(15)-C(14)-C(13) 125.3(5) C(16)-C(15)-C(14) 124.4(5) C(16)-C(15)-C(41) 121.3(5) C(14)-C(15)-C(41) 114.3(5) N(4)-C(16)-C(15) 125.9(5) N(4)-C(16)-C(17) 108.1(5) C(15)-C(16)-C(17) 126.0(5) C(18)-C(17)-C(16) 108.3(5) C(17)-C(18)-C(19) 106.9(5) N(4)-C(19)-C(20) 124.6(5) N(4)-C(19)-C(18) 109.4(4) C(20)-C(19)-C(18) 125.8(5) C(1)-C(20)-C(19) 124.6(5) C(1)-C(20)-C(51) 114.6(5) C(19)-C(20)-C(51) 120.7(5) C(25)-C(21)-C(22) 105.9(5) C(25)-C(21)-C(5) 129.9(5) C(22)-C(21)-C(5) 123.9(5) C(25)-C(21)-Fe(1) 69.5(3) C(22)-C(21)-Fe(1) 68.0(3) C(5)-C(21)-Fe(1) 131.4(4) C(23)-C(22)-C(21) 109.0(6) C(23)-C(22)-Fe(1) 69.9(4) C(21)-C(22)-Fe(1) 71.0(3) C(22)-C(23)-C(24) 107.6(6) C(22)-C(23)-Fe(1) 69.4(4) C(24)-C(23)-Fe(1) 70.4(4) C(25)-C(24)-C(23) 108.3(5) C(25)-C(24)-Fe(1) 70.3(3) C(23)-C(24)-Fe(1) 69.0(4) C(24)-C(25)-C(21) 109.2(5) C(24)-C(25)-Fe(1) 69.8(3) C(21)-C(25)-Fe(1) 70.0(3) C(30)-C(26)-C(27) 107.1(7) C(30)-C(26)-Fe(1) 70.5(4) C(27)-C(26)-Fe(1) 69.6(4) C(28)-C(27)-C(26) 107.5(7) C(28)-C(27)-Fe(1) 70.4(4) C(26)-C(27)-Fe(1) 69.3(4) C(29)-C(28)-C(27) 108.6(7) C(29)-C(28)-Fe(1) 70.1(4) C(27)-C(28)-Fe(1) 69.6(4) C(28)-C(29)-C(30) 109.2(7) C(28)-C(29)-Fe(1) 70.3(4) C(30)-C(29)-Fe(1) 70.3(4) C(29)-C(30)-C(26) 107.6(7) C(29)-C(30)-Fe(1) 69.8(4) C(26)-C(30)-Fe(1) 69.0(4) C(35)-C(31)-C(32) 106.4(5) C(35)-C(31)-C(10) 123.6(5) C(32)-C(31)-C(10) 129.8(5)
C(35)-C(31)-Fe(2) 68.0(3) C(32)-C(31)-Fe(2) 69.1(3) C(10)-C(31)-Fe(2) 131.1(4) C(33)-C(32)-C(31) 109.0(6) C(33)-C(32)-Fe(2) 69.0(4) C(31)-C(32)-Fe(2) 70.8(3) C(34)-C(33)-C(32) 108.1(6) C(34)-C(33)-Fe(2) 69.7(4) C(32)-C(33)-Fe(2) 70.6(4) C(33)-C(34)-C(35) 107.2(6) C(33)-C(34)-Fe(2) 69.7(4) C(35)-C(34)-Fe(2) 69.3(3) C(31)-C(35)-C(34) 109.3(6) C(31)-C(35)-Fe(2) 71.7(3) C(34)-C(35)-Fe(2) 69.8(3) C(40)-C(36)-C(37) 104.8(8) C(40)-C(36)-Fe(2) 70.6(5) C(37)-C(36)-Fe(2) 70.7(4) C(38)-C(37)-C(36) 107.5(8) C(38)-C(37)-Fe(2) 70.6(4) C(36)-C(37)-Fe(2) 68.1(5) C(39)-C(38)-C(37) 110.0(8) C(39)-C(38)-Fe(2) 71.0(5) C(37)-C(38)-Fe(2) 70.3(4) C(38)-C(39)-C(40) 109.7(9) C(38)-C(39)-Fe(2) 71.2(4) C(40)-C(39)-Fe(2) 70.1(5) C(39)-C(40)-C(36) 107.9(8) C(39)-C(40)-Fe(2) 70.6(5) C(36)-C(40)-Fe(2) 68.4(4) C(42)-C(41)-C(45) 105.9(4) C(42)-C(41)-C(15) 130.0(5) C(45)-C(41)-C(15) 123.8(5) C(42)-C(41)-Fe(3) 68.4(3) C(45)-C(41)-Fe(3) 67.8(3) C(15)-C(41)-Fe(3) 132.0(4) C(43)-C(42)-C(41) 108.3(5) C(43)-C(42)-Fe(3) 69.2(3) C(41)-C(42)-Fe(3) 70.9(3) C(44)-C(43)-C(42) 108.7(5) C(44)-C(43)-Fe(3) 69.8(3) C(42)-C(43)-Fe(3) 69.9(3) C(43)-C(44)-C(45) 108.0(5) C(43)-C(44)-Fe(3) 69.9(3) C(45)-C(44)-Fe(3) 69.6(3) C(44)-C(45)-C(41) 109.0(5) C(44)-C(45)-Fe(3) 69.7(3) C(41)-C(45)-Fe(3) 71.2(3) C(47)-C(46)-C(50) 108.1(6) C(47)-C(46)-Fe(3) 69.8(4) C(50)-C(46)-Fe(3) 69.7(3) C(46)-C(47)-C(48) 109.1(6) C(46)-C(47)-Fe(3) 70.0(3) C(48)-C(47)-Fe(3) 70.3(4) C(47)-C(48)-C(49) 106.6(6) C(47)-C(48)-Fe(3) 69.2(4)
122
C(49)-C(48)-Fe(3) 68.9(3) C(50)-C(49)-C(48) 108.2(6) C(50)-C(49)-Fe(3) 69.7(4) C(48)-C(49)-Fe(3) 70.3(4) C(46)-C(50)-C(49) 108.0(6) C(46)-C(50)-Fe(3) 70.0(4) C(49)-C(50)-Fe(3) 69.6(4) C(55)-C(51)-C(52) 106.2(5) C(55)-C(51)-C(20) 130.5(5) C(52)-C(51)-C(20) 123.2(5) C(55)-C(51)-Fe(4) 69.3(3) C(52)-C(51)-Fe(4) 68.3(3) C(20)-C(51)-Fe(4) 130.2(4) C(53)-C(52)-C(51) 109.3(5) C(53)-C(52)-Fe(4) 70.5(3) C(51)-C(52)-Fe(4) 70.8(3) C(54)-C(53)-C(52) 107.4(5) C(54)-C(53)-Fe(4) 69.6(3) C(52)-C(53)-Fe(4) 68.7(3) C(53)-C(54)-C(55) 108.4(5) C(53)-C(54)-Fe(4) 70.0(3) C(55)-C(54)-Fe(4) 70.0(3) C(54)-C(55)-C(51) 108.7(5) C(54)-C(55)-Fe(4) 69.5(3) C(51)-C(55)-Fe(4) 70.0(3) C(57)-C(56)-C(60) 106.9(6) C(57)-C(56)-Fe(4) 69.3(4) C(60)-C(56)-Fe(4) 69.2(4) C(58)-C(57)-C(56) 108.7(6) C(58)-C(57)-Fe(4) 70.3(4) C(56)-C(57)-Fe(4) 70.2(4) C(59)-C(58)-C(57) 108.0(7) C(59)-C(58)-Fe(4) 70.1(4) C(57)-C(58)-Fe(4) 69.4(4) C(58)-C(59)-C(60) 108.8(6) C(58)-C(59)-Fe(4) 70.1(4) C(60)-C(59)-Fe(4) 69.5(4)
C(59)-C(60)-C(56) 107.6(6) C(59)-C(60)-Fe(4) 70.1(4) C(56)-C(60)-Fe(4) 69.9(4) C(65)-C(61)-C(62) 105.7(6) C(65)-C(61)-Fe(5) 69.3(4) C(62)-C(61)-Fe(5) 68.3(4) C(65)-C(61)-In(1) 127.6(5) C(62)-C(61)-In(1) 126.7(6) Fe(5)-C(61)-In(1) 127.2(3) C(63)-C(62)-C(61) 109.7(8) C(63)-C(62)-Fe(5) 69.2(4) C(61)-C(62)-Fe(5) 70.6(4) C(64)-C(63)-C(62) 106.4(7) C(64)-C(63)-Fe(5) 70.1(4) C(62)-C(63)-Fe(5) 69.6(4) C(63)-C(64)-C(65) 108.5(7) C(63)-C(64)-Fe(5) 69.4(5) C(65)-C(64)-Fe(5) 69.9(4) C(61)-C(65)-C(64) 109.6(7) C(61)-C(65)-Fe(5) 70.8(4) C(64)-C(65)-Fe(5) 69.2(4) C(70)-C(66)-C(67) 108.1(8) C(70)-C(66)-Fe(5) 71.8(4) C(67)-C(66)-Fe(5) 70.2(5) C(68)-C(67)-C(66) 107.3(7) C(68)-C(67)-Fe(5) 70.6(4) C(66)-C(67)-Fe(5) 69.0(4) C(67)-C(68)-C(69) 108.2(8) C(67)-C(68)-Fe(5) 69.2(5) C(69)-C(68)-Fe(5) 70.2(4) C(70)-C(69)-C(68) 107.7(7) C(70)-C(69)-Fe(5) 70.5(4) C(68)-C(69)-Fe(5) 69.6(4) C(69)-C(70)-C(66) 108.7(7) C(69)-C(70)-Fe(5) 70.1(4) C(66)-C(70)-Fe(5) 68.2(5)
______________________________________________________________________________
Anisotropic displacement parameters (A^2 x 10^3)
The anisotropic displacement factor exponent takes the form:
-2 pi^2 [ h^2 a*^2 U11 + ... + 2 h k a* b* U12 ______________________________________________________________________________
U11 U22 U33 U23 U13 U12 ______________________________________________________________________________
In(1) 26(1) 23(1) 20(1) -3(1) -5(1) -11(1) Fe(1) 39(1) 27(1) 31(1) -9(1) -10(1) -13(1) Fe(2) 44(1) 45(1) 23(1) -14(1) 3(1) -25(1) Fe(3) 33(1) 23(1) 23(1) -3(1) -7(1) -12(1)
123
Fe(4) 38(1) 30(1) 21(1) -2(1) -3(1) -18(1) Fe(5) 39(1) 35(1) 48(1) -16(1) -8(1) -8(1) N(1) 32(3) 26(3) 16(2) -3(2) -3(2) -15(2) N(2) 31(2) 20(2) 18(2) -3(2) -3(2) -13(2) N(3) 25(2) 26(3) 19(2) -5(2) -1(2) -15(2) N(4) 20(2) 24(2) 20(2) -2(2) -5(2) -8(2) C(1) 34(3) 21(3) 23(3) -7(2) 0(2) -12(2) C(2) 24(3) 31(3) 27(3) -7(3) -2(3) -12(2) C(3) 26(3) 25(3) 27(3) -4(3) -6(3) -9(2) C(4) 26(3) 21(3) 26(3) -3(2) -7(2) -11(2) C(5) 21(3) 22(3) 28(3) -8(2) -7(2) -9(2) C(6) 31(3) 24(3) 28(3) -11(3) -11(3) -6(2) C(7) 34(3) 32(3) 19(3) -6(3) -8(2) -16(3) C(8) 34(3) 36(3) 19(3) -8(3) -4(3) -15(3) C(9) 35(3) 23(3) 17(3) -2(2) -5(2) -12(2) C(10) 31(3) 24(3) 21(3) -5(2) -5(2) -10(2) C(11) 23(3) 20(3) 26(3) -6(2) 0(2) -9(2) C(12) 29(3) 19(3) 25(3) -5(2) 0(2) -9(2) C(13) 26(3) 25(3) 26(3) -8(3) -2(2) -11(2) C(14) 31(3) 20(3) 24(3) -7(2) -1(2) -14(2) C(15) 25(3) 24(3) 22(3) -6(2) -1(2) -12(2) C(16) 26(3) 24(3) 23(3) -7(2) -3(2) -11(2) C(17) 36(3) 30(3) 18(3) -3(2) -8(2) -14(3) C(18) 29(3) 38(3) 20(3) -7(3) -1(2) -17(3) C(19) 29(3) 22(3) 17(3) 2(2) -8(2) -9(2) C(20) 36(3) 19(3) 18(3) -1(2) -1(2) -12(2) C(21) 23(3) 28(3) 31(3) -13(3) -1(2) -10(2) C(22) 35(3) 33(3) 34(3) -9(3) -6(3) -15(3) C(23) 36(3) 52(4) 50(4) -19(4) -12(3) -22(3) C(24) 38(3) 35(4) 44(4) -11(3) -16(3) -10(3) C(25) 36(3) 28(3) 30(3) -8(3) -11(3) -9(3) C(26) 74(5) 39(4) 48(4) -17(4) -13(4) -28(4) C(27) 84(6) 25(4) 47(4) -10(3) -11(4) -15(4) C(28) 51(4) 48(5) 56(5) -31(4) -4(4) -7(4) C(29) 52(4) 53(5) 52(5) -30(4) 4(4) -24(4) C(30) 86(5) 39(4) 35(4) -17(3) -3(4) -29(4) C(31) 43(3) 35(3) 22(3) -8(3) -3(3) -24(3) C(32) 54(4) 39(4) 23(3) -7(3) -2(3) -30(3) C(33) 80(5) 59(5) 25(3) -17(3) 11(4) -54(4) C(34) 41(4) 84(6) 35(4) -35(4) 12(3) -36(4) C(35) 35(3) 53(4) 27(3) -20(3) 7(3) -25(3) C(36) 54(5) 134(10) 132(10) -115(9) 47(6) -53(6) C(37) 90(6) 30(4) 60(5) -20(4) -38(5) 4(4) C(38) 63(5) 47(4) 58(5) -27(4) 10(4) -34(4) C(39) 90(6) 62(6) 69(6) -27(5) -26(5) -35(5) C(40) 237(15) 87(7) 18(4) -19(5) 11(6) -111(9) C(41) 26(3) 21(3) 21(3) -1(2) -7(2) -11(2) C(42) 29(3) 26(3) 23(3) 0(2) -2(2) -15(2) C(43) 38(3) 23(3) 27(3) 0(3) -15(3) -14(2) C(44) 32(3) 38(4) 26(3) -4(3) -3(3) -22(3) C(45) 31(3) 31(3) 19(3) -6(3) 3(2) -17(3) C(46) 53(4) 36(4) 26(3) 4(3) -13(3) -19(3) C(47) 44(4) 27(3) 48(4) 0(3) -15(3) -10(3) C(48) 53(4) 24(3) 34(4) -4(3) -3(3) -15(3) C(49) 46(4) 29(3) 37(4) 2(3) -10(3) -18(3) C(50) 49(4) 28(3) 26(3) 5(3) -6(3) -17(3)
124
C(51) 26(3) 32(3) 23(3) -3(3) -6(2) -12(2) C(52) 26(3) 34(3) 26(3) -4(3) -3(2) -17(2) C(53) 35(3) 51(4) 34(4) -7(3) -1(3) -29(3) C(54) 33(3) 42(4) 21(3) -10(3) 3(3) -12(3) C(55) 33(3) 31(3) 23(3) -5(3) -8(3) -11(3) C(56) 75(5) 37(4) 29(4) 1(3) -14(3) -26(4) C(57) 63(5) 32(4) 48(4) 5(3) -26(4) -19(3) C(58) 46(4) 36(4) 38(4) 2(3) -2(3) -14(3) C(59) 65(5) 35(4) 41(4) -15(3) -6(4) -14(3) C(60) 79(5) 33(4) 33(4) -2(3) -9(4) -26(4) C(61) 30(3) 27(3) 61(5) -15(3) -8(3) -13(3) C(62) 55(4) 52(5) 65(5) -27(4) -23(4) -10(4) C(63) 69(5) 38(5) 119(9) -43(5) -40(6) 3(4) C(64) 44(4) 31(4) 106(8) -21(5) -12(5) -11(3) C(65) 41(4) 31(4) 66(5) -9(4) -10(4) -9(3) C(66) 58(5) 92(7) 47(5) -21(5) 4(4) -19(5) C(67) 45(4) 60(6) 98(7) -51(6) -2(5) -2(4) C(68) 53(4) 43(4) 80(6) -6(4) -19(4) -20(4) C(69) 58(5) 52(5) 59(5) -14(4) -5(4) -31(4) C(70) 30(3) 45(4) 57(5) -6(4) 4(3) -18(3) _______________________________________________________________________
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