Schematic IBr - (CO 2 ) n Photodissociation h + IBr - → I - + Br or I + Br - h 10 sec Uncaged Caged
Time-resolved dynamics with partially solvated anions W. Carl
Lineberger S pectroscopy for Dynamics Minisymposium Molecular
Spectroscopy 2007 Thanks to Rich Loomis Solvation Dynamics in
Cluster Ions Size-selected clusters as a bridge or a unique entity?
Achieve asymmetric environments more extreme than in bulk Affords
access to solvent electric fields that enhance effects Can clarify
understanding of condensed phase theories Can carry out more
sophisticated simulations than in bulk Not intended to be a mimic
of bulk Close interplay between experiment and theory is crucial
Structure of solvation shell Effect of chromophore: I 2 -, IBr -
Charge localization upon dissociation Breaking the symmetry Caging
viewed in the time domain Todd Sanford Jack Barbera Robert Parson
Annette Svendsen Josh Martin Matt Thompson Vladimir Dribinski Josh
Darr Schematic IBr - (CO 2 ) n Photodissociation h + IBr - I - + Br
or I + Br - h 10 sec Uncaged Caged Methodology Ionic product
distributions ~10 s after dissociation caged IBr (CO 2 ) k uncaged
I (CO 2 ) k, Br - (CO 2 ) m Caging probability Solvent evaporation
energetics Ultrafast pump - probe recombination dynamics
Time-resolved picture of recombination Theory (Parson and Thompson)
ab initio electronic structure for solute Rigid solvent,
polarizations included; cluster structure Nonadiabatic molecular
dynamics w/solvent allowed to polarize solute First, a brief review
of I 2 - electronic structure and I 2 - (CO 2 ) n cluster dynamics
as a reference I 2 - Valence Shell Potentials J. Faeder, N.
Delaney, P, Maslen and R. Parson M. Zanni and D.M. Neumark I-I bond
length, Angstroms Energy, eV g,1/2 g,3/2 u,3/2 u,1/2 u,1/2 + g,1/2
+ I( 2 P 1/2 ) + I I( 2 P 3/2 ) + I 1.0 eV 0.6 eV I 2 - A 2 caging
probability Caged fragment fraction 82% I 2 (OCS) 4,5 18% I (OCS)
8,9 What is the time required for the dissociated I 2 - to
recombine? I 2 - (CO 2 ) 8-17 A 2 Recombination ps recombination
time, decreasing with solvation What is the physical picture of the
caging? N. Delaney, J. Faeder, P. E. Maslen, R. Parson, J. Phys.
Chem. A 101, 8147 (1997). Electric field (solvent) perturbation of
I 2 - states I-I bond length () g,1/2 u,3/2 2 u,1/2 u,1/2 + g,1/2 +
I * ( 2 P 1/2 ) + I I( 2 P 3/2 ) + I g,3/2 Isolated I 2 I-I bond
length () g,1/2 u,3/2 2 u,1/2 u,1/2 + g,1/2 + I * ( 2 P 1/2 ) + I
I( 2 P 3/2 ) + I g,3/2 I 2 in solvent E field Asymmetric solvation
driving recombination: Solvent induced modification of solute
electronic structure. Asymmetry (solvent E solute) from 3-4 CO 2
solvents produces curve crossings for levels (I and I*) separated
by 1 eV. Recombination time ~10 ps, decreasing with additional
solvation. Also true for excitations leading to I*. Similar, rapid
recombination seen for OCS, N 2 O, CO 2 and Ar solvating I 2 - What
happens when IBr - or ICl - replaces I 2 - ? Recombination
mechanism ICl - (CO 2 ) 4 IBr - (CO 2 ) 8 Initial solvation occurs
about the smaller ion! We can now test the electron transfer
picture. Breaking the symmetry R I-Br, Br+ I - Br*+ I - Br - + I Br
- +I* I - +I* I - +I IBr - and I 2 - Valence Shell Potentials
Robert Parson and Matt Thompson R I-I, What do the calculated
cluster structures look like? IBr - (CO 2 ) n Minimum Energy
Structures R. Parson and M. Thompson R I-Br, Br+ I - Br*+ I - Br -
+ I Br - +I* First, look at the dissociation products following
excitation to the A 2 state. IBr - based (caged) IBr - (CO 2 ) n A
2 state ionic photoproducts Next, look at the uncaged I - -based
products. I - based (uncaged) IBr - based (caged) IBr - (CO 2 ) n A
2 state ionic photoproducts And the uncaged Br - -based products. I
- based (uncaged) Br - based (charge transfer) IBr - based (caged)
IBr - (CO 2 ) n A 2 state ionic photoproducts Br - -based products
confirm electron transfer in recombination. And the uncaged Br -
-based products. n Caging Percentage A 2 State Caging Efficiency I
2 - (CO 2 ) n n IBr - (CO 2 ) n In the A state, IBr - caging
behaves like I 2 -. By analogy, ps recombination is expected. IBr -
(CO 2 ) 8 A 2 State Recombination Recombination in 1000 ps, even
for 100 % caging!! 797 nm pump and probe 100 % recombination to X 2
1000 ps recombination time!! Every IBr - ion reaches the ground
state, despite the very long recombination time. Very different
from I 2 -, and might involve a solvent-induced excited state trap
Try IBr - (CO 2 ) 10 IBr - (CO 2 ) 8 A 2 Summary IBr - (CO 2 ) 10 A
2 State Recombination So we next remove solvent: IBr - (CO 2 ) 5.
Recombination still takes 900 ps. Presumably, IBr - is still
trapped in the 2 state. IBr - (CO 2 ) 5 A 2 State Recombination
Coherence peak 12 ps recombination!! 1 ps delay Cage fraction 797
nm 12 ps recombination time 1 ps delay before any recombination
seen What happens when we add a 6 th solvent? With 8 solvents, we
must reach 1000 ps IBr - (CO 2 ) 5 A 2 Summary IBr - (CO 2 ) 6 A 2
State Recombination Cage fraction is ~95 %, recombination in 15 ps;
2 ps delay Coherence peak 15 ps recovery Summarizing the data, X 2
- (CO 2 ) n A 2 Recombination Time Compare with the understandable
I 2 - recombination IBr - X 2 - (CO 2 ) n A 2 Recombination Time
Huge difference for what was supposed to be a minor change! I2-I2-
We need theory (and more experiments!)! IBr - *Robert Parson and
Matt Thompson Theoretical Methods* (1) Solute ab initio Eigenstates
of bare anion icMRCISD calculated via MOLPRO S-O coupling,
transition DMA and transition angular momentum calculated
Solute-solvent interactions Distributed multipoles for solute
charge density Solvent polarizes solute wavefunctions Cluster
structures Sample 200 configurations from 1 ns, 80 K molecular
dynamics simulation on the ground electronic surface Find typical
structures Calculate initial solvent coordinate Model Hamiltonian
*Robert Parson and Matt Thompson Theoretical Methods* (2) Full
nuclear dynamics w/rigid CO 2 Classical path surface hopping using
least switches - Tully Electronic deg of freedom quantum New IBr -
calculation at each time step Nonadiabatic molecular dynamics Need
to reduce massive md trajectory data sets to a comprehensible
packet of information Solvent Coordinate, is the c hange in energy
when charge of e is moved from one solute atom to the other For a
fixed solute configuration, provides a measure of the solvent
asymmetry Plots of R(I-Br) vs. provide a reduced dimensionality
view of solvent and charge movement throughout a trajectory IBr -
(CO 2 ) n Initial Solvent Asymmetry (from 200 samples of 1 ns, 80 K
trajectory) So, lets look at a single IBr - (CO 2 ) 8 50 ps
trajectory. , eV A single IBr - (CO 2 ) 8 trajectory R I-Br, Br+I -
Br*+I - Br - +I Br - +I* Now look at an ensemble of trajectories. R
(I-Br), X A set of IBr - (CO 2 ) 8 trajectories R I-Br, Br+I -
Br*+I - Br - +I Br - +I* R(I Br), 01-2 , eV At 50 ps, 89 % of the
trajectories are still on the A surface! How well do experiment and
theory compare? Each cluster size has an ensemble of a few hundred
to a few thousand trajectories. Construct a histogram of the time
that each successful trajectory reaches some small energy in the
ground state. The resulting data fit as well as was appropriate to
a [1 exp(-t/ )] form, consistent with experimental results. How do
theory and experiment compare? Recombination Time Dependence IBr -
(CO 2 ) n Absorption Recovery Time Experiment and Theory Agreement
is remarkable, but we need more experiments Solute asymmetry has
unexpected, dramatic effect on caging dynamics Excited state
trapping arising from solvent 8 12 solvents Simulations capture a
remarkable amount of the important physics! Essential need for both
theory and experiment Summarizing And thank you for your attention!
A 2 1/2 B 2 1/2 X 2 1/2 Br - + I * Br - + I I - + Br I - + Br*
Energy (eV) Calculations by M.Thompson and R. Parson IBr - (CO 2 )
8 Potentials with CO 2 frozen at minimum energy configuration
Solvent-induced electronic relaxation IBr - (CO 2 ) 8 2 ns
trajectories R I-Br, Br+I - Br*+I - Br - +I Br - +I* R(I Br), 01-2
, eV IBr - (CO 2 ) 8 : A single trajectory R I-Br, Br+I - Br*+I -
Br - +I Br - +I* R(I Br), 01-2 , eV IBr - (CO 2 ) 8 50 ps
trajectories At 50 ps, 89 % of the trajectories are on the A
surface! IBr - (CO 2 ) 5 A 2 State Recombination Even minor
features reproduce! Coherence peak MD Simulation: IBr (CO 2 ) n 790
nm 50 ps products What about the predicted recombination rate?
Clear evidence for solvent induced trapping in A state over a small
range of solvent sizes! Fraction Caged 0.55 eV 674 nm 0.35 eV 760
nm 0.30 eV 790 nm Parent Cluster (n) IBr - (CO 2 ) n A 2 Caging
efficiency depends on energy release One expects only a one solvent
shift for the highest KE release. We see more! IBr - (CO 2 ) n 790
nm A 2 Caging Now add 50 ps simulation results I - based (uncaged)
Br - based (charge transfer) IBr - based (caged) Experiment IBr -
(CO 2 ) n 790 nm I - and Br - products I - based (uncaged) Br -
based (charge transfer) Simulation is solid line - qualitatively OK
IBr - (CO 2 ) n 790 nm IBr - Products 50 ps simulation This
modeling was done before the time-resolved experiment; no attention
was paid to the IBr - electronic state. A state trapping for 8 n
12. IBr - (CO 2 ) n X and A state distributions 50 ps into
trajectory What about the predicted recombination rate? IBr - (CO 2
) n Minimum Energy Structures R. Parson and M. Thompson IBr - (CO 2
) n R. Parson and M. Thompson large average R. Parson and M.
Thompson large average The cage effect: Time-resolved dynamics of
partially solvated dihalides
