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Oxidation products of terpenes: synthesis of reference
compounds and novel sampling technique
Jevgeni ParshintsevJoonas Nurmi, Kari Hartonen and Marja-Liisa
Riekkola
University of Helsinki
Finland
Background
• Aerosols are relatively stable suspension of solid or liquid particle in a gas, diameter ~0.002µm – 100 µm
• Either directly emitted into the atmosphere or formed there by chemical reactions (primary and secondary aerosols)
Impact on the energy balance of the planet
direct indirect
-scattering &-absorption of solar radiation In the atmosphere
alter the: -formation-precipitation efficiency &-optical properties of clouds
Aerosols are cooling the Earth’s surface immediately below them
• Directly:
lbexteI
I 0
Where I and I0 are the incident and transmitted light intensities respectively,L is the pathlength of the light beam, and bext is the extinction coefficient, (length)-1
pgext bbb spapsgagext bbbbb
Light extinctions due to gaseous and particulate absorption and scattering
BUT: light absorption by NO2(one,which contribute significantly) is usually much Less than the total light scattering and absorption by particles
Scattering is significant if D≈λ
-and indirectly:Aerosol particles are “seeds” to start the formation of cloud droplets.
Aerosol concentration increase => the water gets spread over many more particles => smaller drops
Clouds with smaller drop:
-reflect more sunlight
-such clouds last longer
Both effects increase the amount of sunlight that is reflected to space without reaching the surface.
It is thought that aerosol cooling may partially offset expected
global warming that is attributed to increases in the amount of carbon dioxide from human
activity…
Atmospheric aerosols
http://www.ems.psu.edu/~lno/Meteo437/Aerosol.jpg, 31.7.06
Why sesquiterpenes?
• ~9% of all non-methan VOCs in aerosols• almost unknown (compare to monoterpenes)• Have much higher aerosol potential than
monoterpenes. Example:• 2% of total biogenic VOC- emission is assumed
to be β-caryophyllene in Scandinavian atmosphere, the contribution by caryophyllene to the total biogenic secondary aerosol formation was estimated to be 12%!
C15H24
Analysis of sesquiterpenes oxidation products
• Usually collected on impactor plate or filter
• Extracted by proper solvent
• Analyzed by GC-MS (derivatization is needed if too polar)
• Identification & quantitation are almost impossible nowadays because of:
• Leak of reference materials, small amounts & great variety
Conventional collection techniques
• Impactor, filter (usually quartz)
http://jolisfukyu.tokai-sc.jaea.go.jp/fukyu/tayu/ACT03E/img/09IMG/09_01.jpghttp://www.menlh.go.id/apec_vc/osaka/eastjava/hap_en/filter/5-3.gif 18.11.07
Synthesis, isolation
• Solution of β-caryophyllene (~1000ppm) in dichloromethane was ozonolyzed by bubbling the ozone (produced by corona discharge) through the mixture
• Reaction was stopped when potassium iodide solution trap turned yellow (unreacted ozone, reaction time appr. 2h) O3 2KI H2O I2 2KOH O2
• 100 mg of Zn-powder and 10 ml of acetic acid/water mixture was added and refluxed for 1h
• Compounds were extracted by LLE to the dichloromethane
• Products were isolated and purified by flash-chromatography
Scheme of oxidation of β-caryophyllene
Paineistettu pylväskromatografialaitteisto
Identification
• Mass-spectrometry with ESI- and EI-ionization and nuclear magnetic resonance spectroscopy were applied
59
10
11CH312
3
21
O
CH24
CH38
CH37
O
H6
H6
48
9
10CH311
3
O
CH37
CH36
2
O
1
OH5
H5
Picture 1. Structures of β-nocaryophyllone aldehyde (left) and β-caryophyllene aldehyde (right) confirmed by NMR.
Structures
Analysis of aerosol samples
• Self made standards were used in the analysis of ambient aerosol samples collected in Hyytiälä in 2003
• GC-MS and GC*GC-FID were used
• β-nocaryophyllone aldehyde was positively identified in one sample with amount of 17ng/m3
Parshintsev et al. accepted to Analytical and Bioanalytical Chemistry
Conclusions I
• Two β-caryophyllene oxidation products were synthesized, isolated and analyzed for the precise structures for the first time
• Standards were used in analysis of ambient aerosol samples
• Presence of studied compounds in the samples proves their participation in biogenic aerosol formation
• However, more oxidation products of terpenes should be synthesized, to make their analysis possible, in order to understand the contribution of sesquiterpenes oxidation products to the biogenic aerosol chemistry
Part II. Working principles of PILS
• particle growth in a mixing condensation particle counter
• droplet collection by a single jet inertial impactor
• used off-line, but continuous sample flow can provide on-line applications through SPE to HPLC or directly to API-MS
PILS
Weber et al. Aerosol Science and Technology 35: 718–727 (2001)
PILS
• Sample air flow 16.7 L/min (can be increased)
• Transport flow can be changed to relatively unpolar solvent
• Size separation before PILS, such as virtual impactor
• Gases removed by KOH, H3PO4, XAD-denuders
Disadvantages
• Needs to be cleaned frequently (can be automated by running methanol/water steam through the system)
• 10% of gases passes through the denuders => “zero” samples should be run often
Aerosol sampling
• Samples were collected during spring and summer 2007 in Hyytiälä (SMEARII-station), Finland
• Filter sampling was used as reference
• Samples were analyzed off-line: LLE to dichloromethane, concentration, GC-MS
Parshintsev et al. (2007) Manuscript in preparation
Preliminary results
• Pinonaldehyde was found in all samples in great amounts
• Correlation with even/non-event was noticed due to the better time resolution
• Quantitation of other compounds is in progress
Comparison with filter sampling
• Two hours filter samples showed amounts under LOD
• Only day or night samples contained amounts exceeding LOD
Event week (except 103)
0,00
10,00
20,00
30,00
40,00
50,00
60,00
70,00
102,00 103,00 104,00 105,00 106,00 107,00 108,00 109,00
Non-event week
0,00
10,00
20,00
30,00
40,00
50,00
60,00
70,00
113,00 114,00 115,00 116,00 117,00 118,00 119,00
Conclusions II
• Time resolution of PILS is better than of filter sampling
• Less artifacts
• On-line possibility
• Transport flow can be 2-propanol (improves the collection efficiency for less polar compounds)
• However, optimization is still needed