| [1] | Seinfeld J H,Pandis S N. Atmospheric Chemistry and Physics:From Air Pollution to Climate Change[M].New York:Wiley-Interscience,1998 |
| [2] | 汪午,王省良,李黎,等. 天然源二次有机气溶胶的研究进展[J]. 地球化学,2008,37(1):77-86 |
| [3] | Charlson R L,Schwartz S,Hales J M,et al. Climate forcing by anthropogenic aerosols[J]. Science,1992,255(5043):423-430 |
| [4] | Kanakidou M,Seinfeld J H,Pandis S N,et al. Organic aerosol and global climate modeling:A review[J]. Atmospheric Chemistry and Physics,2005,5(4):1053-1123 |
| [5] | Griffin R J,Cocker D R,FlaganR C,et al. Organic aerosol formation from the oxidation of biogenic hydrocarbons[J]. Journal of Geophysical Research,1999,104:3555-3567 |
| [6] | 杨晓璐,陈建华,邓建国,等. 烯烃臭氧化反应机制的研究进展[J].环境化学,2013,32(11):2050-2058 |
| [7] | Glasius M,Lahaniati M,Calogirou A,et al. Carboxylic acids in secondary aerosols from oxidation of cyclic monoterpenes by ozone[J]. Environmental Science & Technology,2000,34:1001-1010 |
| [8] | Ma Y,Russell A T,Marston G. Mechanism for the formation of secondary organic aerosol components from the gas-phase ozonolysisof α-pinene[J]. Physical Chemistry Chemical Physics,2008,10:4294-4312 |
| [9] | Camredon M, Hamilton J F, Alam M S,et al.Distribution of gaseous and particulate organic compositionduring dark α-pinene ozonolysis[J]. Atmospheric Chemistry and Physics,2010,10:2893-2917 |
| [10] | 刘兆荣,曾立民,陈忠明,等. 单萜烯臭氧化反应产物的研究[J]. 环境化学,1999,18(4):321-326 |
| [11] | Lee B H, Pierce J R, Engelhart G J. Volatility of secondary organic aerosol from the ozonolysis of monoterpenes[J]. Atmospheric Environment,2011,45:2443-2452. |
| [12] | Zhao Z, Hao J M, Li J H, et al. Second organic aerosol formation from the ozonolysis of a-pinene in the presence of dry submicron ammonium sulfate aerosol[J]. Journal of Environmental Sciences,2008, 20(10):1183-1188 |
| [13] | 袁成, 马嫣, 陈敏东. 烯烃气相臭氧化反应机理的研究进展[J]. 环境化学,2013,32(2):177-187 |
| [14] | Moore R H,Nenes A,Medina J. Scanning mobility CCN analysis-a method for fast measurements of size-resolved CCN distributions and activation kinetics[J]. Aerosol Science & Technology,2010,44:861-871 |
| [15] | Lopez-Hilfiker F D,Mohr C,Ehn M,et al. A novel method for online analysis of gas and particle composition:Description and evaluation of a Filter Inlet for Gases and AEROsols(FIGAERO)[J]. Atmospheric Measurement Technology,2014,7:983-1001 |
| [16] | Huey L G. Measurement of trace atmospheric species by chemical ionization mass spectrometry:Speciation of reactive nitrogen and future directions[J]. Mass Spectrometry Reviews,2007,26:166-184 |
| [17] | Sellegri K,Umann B,HankeM,et al.Deployment of a ground-based CIMS apparatus for the detection of organic gases in the boreal forest during the QUEST campaign[J]. Atmospheric Chemistry and Physics,2005,5:357-372 |
| [18] | Kurtén T, Bonn B, Vehkamäki H, et al. Computational study of the reaction between biogenic stabilized Criegee intermediates and sulfuric acid[J]. Journal of Physical Chemistry A,2007,111:3394-3401 |
| [19] | Jiang L, Xu Y S, Ding A Z. Reaction of stabilized Criegee intermediates from ozonolysis of limonene with sulfur dioxide:ab initio and DFT study[J]. Journal of Physical Chemistry A,2010,114:12452-12461 |
| [20] | Sipilä M, Jokinen T, Berndt T, et al. Reactivity of stabilized Criegee intermediates (sCI) from isoprene and monoterpene ozonolysis toward SO2and organic acids[J]. Atmospheric Chemistry and Physics,2014,14:12143-12153 |
| [21] | Boy M, Mogensen D, Smolander S, et al. Oxidation of SO2 by stabilized Criegee Intermediate (sCI) radicals as a crucial source for atmospheric sulphuric acid concentrations[J]. Atmospheric Chemistry and Physics,2013,13:3865-3879 |
| [22] | Mauldin III R L,Berndt T,Sipilä M,et al. A new atmospherically relevant oxidant of sulphurdioxide[J]. Nature,2012,488:193-196 |
| [23] | Vereecken L,Harder H,Novelli A. The reaction of Criegee intermediates with NO, RO2, and SO2, and their fate in the atmosphere[J]. Physical Chemistry Chemical Physics,2012,14:14682-14695 |
| [24] | Kulmala M,Riipinen I,Sipilä M,et al. Toward direct measurement of atmospheric nucleation[J]. Science,2007,318:89-92 |
| [25] | Zhang R,Suh I,Zhao J,et al. Atmospheric new particle formation enhanced by organic acids[J]. Science,2004,304:1487-1490 |
| [26] | Zhao J,KhalizovA,Zhang R. Hydrogen-bonding interaction in molecular complexes and clusters of aerosol nucleation precursors[J]. Journal of Physical Chemistry A,2009,113(4):680-689 |
| [27] | Xu Y,Nadykto A,Yu F. Interaction between common organic acids and trace nucleation species in the earth's atmosphere[J]. Journal of Physical Chemistry A,2010,114(1):387-396 |
| [28] | Lee A,Goldstein A H,Keywood M D,et al. Gas-phase products and secondary aerosol yields from the ozonolysis of ten different terpenes[J].Journal of Geophysical Research,2006,111:D07302,doi:10.1029/2005JD006437 |
| [29] | Turpin B J,Lim H J. Speciescontributions to PM2.5 mass concentrations:revisiting common assumptions for estimating organic mass[J]. Aerosol Science & Technology,2001,35:602-610 |
| [30] | Petters M D,Kreidenweis S M. A single parameter representation of hygroscopic growth and cloud condensation nucleus activity[J]. Atmospheric Chemistry and Physics,2007,7:1961-1971 |
| [31] | Jimenez J L,Canagaratna M R,Donahue N M,et al. Evolution of organic aerosols in the atmosphere[J]. Science,2009,326:1525-1529 |
| [32] | Huff Hartz K,EThomas R,Shaun R F,et al. Cloud condensation nuclei activation of monoterpene and sesquiterpene secondary organic aerosol[J]. Journal of Geophysical Research,2005,110:D14208,doi:10.1029/2004JD005754 |
| [33] | Tang X,Cocker D R,Awuku A A. Are sesquiterpenes a good source of secondary organic cloud condensation nuclei (CCN)? Revisiting β-caryophyllene CCN[J]. Atmospheric Chemistry and Physics,2012,12:8377-8388 |