如果你喜歡寫程序、有興趣讓大氣化學模型在化學上變得更智能，或者喜歡動手、有興趣搗鼓空氣淨化器，無論你是僅比我晚幾天加入暨大的新人，或者相對于我已經是“老”暨大人，都歡迎和我聯系。

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1. 高度化學複雜性的大氣化學模拟

2. 病原體空氣傳播

3. 從疾病傳播和空氣污染兩方面的室内空氣質量研究

（一）論文

1. Jenks O. J., Peng Z., Schueneman M. K., Rutherford M., Handschy A. V., Day D. A., Jimenez J. L., de Gouw J. A.* Effects of Germicidal Ultraviolet Light on Aerosol Formation from Limonene. ACS ES&T Air, 1, 6 (2024), 820-828.

2. Schueneman M. K., Day D. A., Peng Z., Pagonis D., Jenks O. J., de Gouw J., Jimenez J. L.* Secondary Organic Aerosol Formation from the OH Oxidation of Phenol, Catechol, Styrene, Furfural, and Methyl Furfural. ACS Earth Space Chemistry, 8, 6 (2024), 1179-1192.

3. Pan T., Lambe A. T., Hu W.*, He Y., Hu M., Zhou H., Wang X., Hu Q., Chen H., Zhao Y., Huang Y., Worsnop D. R., Peng Z., Morris M. A., Day D. A., Campuzano-Jost P., Jimenez J.-L., Jathar S. H. A comprehensive evaluation of enhanced temperature influence on gas and aerosol chemistry in the lamp-enclosed oxidation flow reactor (OFR) system. Atmospheric Measurement Techniques, 17, 16 (2024), 4915-4939.

4. El Mais A. E. R., D'Anna B., Drinovec L., Lambe A., Peng Z., Petit J.-E., Favez O., Ait-Aissa S., Albinet A.* Insights into secondary organic aerosol formation from the day-and nighttime oxidation of PAHs and furans in an oxidation flow reactor. Atmospheric Chemistry and Physics, 23, 23 (2023), 15077-15096.

5. Peng Z.*, Day D. A., Symonds G., Jenks O. J., Stark H., Handschy A. V., de Gouw J. A., Jimenez J. L.* Significant Production of Ozone from Germicidal UV Lights at 222 nm. Environmental Science & Technology Letters, 10, 8 (2023), 668-674.

6. Peng Z.*, Miller S. L., Jimenez J. L.* Model Evaluation of Secondary Chemistry due to Disinfection of Indoor Air with Germicidal Ultraviolet Lamps. Environmental Science & Technology Letters, 10, 1 (2023), 6-13.

7. Jimenez J. L.*, Peng Z., Pagonis D. Systematic way to understand and classify the shared-room airborne transmission risk of indoor spaces. Indoor Air, 32, 5 (2022), e13025.

8. Greenhalgh T.*, Peng Z., Jimenez J. L., Bahnfleth W. P., Dancer S., Bourouiba L. Quantifying transmission risk of SARS-CoV-2 in different situations. British Medical Journal, 376 (2022), o106.

9. Peng Z., Pineda Rojas A. L., Kropff E., Bahnfleth W., Buonanno G., Dancer S., Kurnitski J., Li Y., Loomans M. G. L. C., Marr L. C., Morawska L., Nazaroff W., Noakes C., Querol X., Sekhar C., Tellier R, Greenhalgh T., Bourouiba L., Boerstra A., Tang J., Miller S., Jimenez J. L.*. Practical Indicators for Risk of Airborne Transmission in Shared Indoor Environments and their Application to COVID-19 Outbreaks. Environmental Science & Technology, 56, 2 (2022), 1125-1137.

10. Hu W.*, Zhou H., Chen W., Ye Y., Pan T., Wang Y., Song W., Zhang H., Deng W., Zhu M., Wang C., Wu C., Ye C., Wang Z., Yuan B., Huang S., Shao M., Peng Z., Day D. A., Campuzano-Jost P., Lambe A. T., Worsnop D. R., Jimenez J. L., Wang X.* Oxidation Flow Reactor Results in a Chinese Megacity Emphasize the Important Contribution of S/IVOCs to Ambient SOA Formation. Environmental Science & Technology, 56, 11 (2022), 6880-6893.

11. Yang X., Yuan B.*, Peng Z., Peng Y., Wu C., Yang S., Li J., Shao M. Inter-comparisons of VOC oxidation mechanisms based on box model: a focus on OH reactivity. Journal of Environmental Sciences, 114 (2022), 286-296.

12. Peng Z.*, Lee-Taylor J., Stark H., Orlando J. J., Aumont B., Jimenez J. L.* Evolution of OH reactivity in NO-free volatile organic compound photooxidation investigated by the fully explicit GECKO-A model. Atmospheric Chemistry and Physics, 21, 19 (2021), 14649-14669.

13. Peng Z., Jimenez J. L.* Exhaled CO2 as a COVID-19 infection risk proxy for different indoor environments and activities. Environmental Science & Technology Letters, 8, 5 (2021), 392-397.

14. Lambe A. T.*, Wood E. C., Krechmer J. E., Majluf F., Williams L. R., Croteau P. L., Cirtog M., Féron A., Petit J.-E., Albinet A., Jimenez J. L., Peng Z.* Nitrate radical generation via continuous generation of dinitrogen pentoxide in a laminar flow reactor coupled to an oxidation flow reactor. Atmospheric Measurement Techniques, 13, 5 (2020), 2397-2411.

15. Peng Z.*, Jimenez J. L.* Radical chemistry in oxidation flow reactors for atmospheric chemistry research. Chemical Society Reviews, 49, 9 (2020), 2570-2616.

16. Liu X., Day D. A., Krechmer J. E., Brown W., Peng Z., Ziemann P. J., Jimenez J. L.* Direct measurements show near-unity mass accommodation coefficients for low- and semi-volatile organic compounds into diverse aerosols. Communications Chemistry, 2 (2019), 98.

17. Jo D. S., Hodzic A., Emmons L. K., Marais E. A., Peng Z., Nault B. A., Hu W., Campuzano-Jost P., Jimenez J. L.* A simplified parameterization of isoprene-epoxydiol-derived secondary organic aerosol (IEPOX-SOA) for global chemistry and climate models: a case study with GEOS-Chem v11-02-rc. Geoscientific Model Development, 12, 7 (2019), 2983-3000.

18. Peng Z., Jimenez J. L.* KinSim: a research-grade, user-friendly, visual kinetics simulator for chemical-kinetics and environmental-chemistry teaching. Journal of Chemical Education, 96, 4 (2019), 806-811.

19. Peng Z.*, Lee-Taylor J., Orlando J. J., Tyndall G. S., Jimenez J. L.* Organic peroxy radical chemistry in oxidation flow reactors and environmental chambers and their atmospheric relevance. Atmospheric Chemistry and Physics, 19, 2 (2019), 813-834.

20. Lambe A. T.*, Krechmer J. E., Peng Z.*, Casar J., Carrasquillo A. J., Raff J. D., Brune W. H., Jimenez J. L., Worsnop D. R. HOx and NOx production in oxidation flow reactors via photolysis of isopropyl nitrite, isopropyl nitrite-d7, and 1,3-propyl dinitrite at λ=254, 350, and 369nm. Atmospheric Measurement Techniques, 12, 1 (2019), 299-311.

21. Hodshire A. L.*, Palm B. B., Alexander M. L., Bian Q., Campuzano-Jost P., Cross E. S., Day D. A., de Sá S. S., Guenther A. B., Hansel A., Hunter J. F., Jud W., Karl T., Kim S., Kroll J. H., Park J. H., Peng Z., Seco R., Smith J. N., Jimenez J. L., Pierce J. R. Constraining nucleation, condensation, and chemistry in oxidation flow reactors using size-distribution measurements and aerosol microphysical modelling. Atmospheric Chemistry and Physics, 18, 16 (2018), 12433-12460.

22. Peng Z., Palm B. B., Day, D. A., Talukdar R. K., Hu W., Lambe A. T., Brune W. H., Jimenez J. L.* Model evaluation of new techniques for maintaining high-NO conditions in oxidation flow reactors for the study of OH-initiated atmospheric chemistry. ACS Earth and Space Chemistry, 2, 2 (2018), 72-86.

23. Peng Z.*, Jimenez J. L.* Modeling of the chemistry in oxidation flow reactors with high initial NO. Atmospheric Chemistry and Physics, 17, 19 (2017), 11991-12010.

24. Hu W., Palm B. B., Day D. A., Campuzano-Jost P., Krechmer J. E., Peng Z., de Sá S. S., Martin S. T., Alexander M. L., Baumann K., Hacker L., Kiendler-Scharr A., Koss A. R., de Gouw J. A., Goldstein A. H., Seco R., Sjostedt S. J., Park J.-H., Guenther A. B., Kim S., Canonaco F., Prévôt A. S. H., Brune W. H., Jimenez J. L.* Volatility and lifetime against OH heterogeneous reaction of ambient isoprene-epoxydiols-derived secondary organic aerosol (IEPOX-SOA). Atmospheric Chemistry and Physics, 16, 18 (2016), 11563-11580.

25. Ortega A. M., Hayes P. L., Peng Z., Palm B. B., Hu W., Day D. A., Li R., Cubison M. J., Brune W. H., Graus M., Carneke C., Gilman J. B., Kuster W. C., de Gouw J., Gutiérrez-Montes C., Jimenez J. L.* Real-time measurements of secondary organic aerosol formation and aging from ambient air in an oxidation flow reactor in the Los Angeles area. Atmospheric Chemistry and Physics, 16, 11 (2016), 7411-7433.

26. Peng Z., Day D. A., Ortega A. M., Palm B. B., Hu W., Stark H., Li R., Tsigaridis K., Brune W. H., Jimenez J. L.* Non-OH chemistry in oxidation flow reactors for the study of atmospheric chemistry systematically examined by modeling. Atmospheric Chemistry and Physics, 16, 7 (2016), 4283-4305.

27. Palm B. B., Campuzano-Jost P., Ortega A. M., Day D. A., Kaser L., Jud W., Karl T., Hansel A., Hunter J. F., Cross E. S., Kroll J. H., Peng Z., Brune W. H., Jimenez J. L.* In situ secondary organic aerosol formation from ambient pine forest air using an oxidation flow reactor. Atmospheric Chemistry and Physics, 16, 5 (2016), 2943-2970.

28. Peng Z., Day D. A., Stark H., Li R., Lee-Taylor J., Palm B. B., Brune W. H., Jimenez J. L.* HOx radical chemistry in oxidation flow reactors with low-pressure mercury lamps systematically examined by modeling. Atmospheric Measurement Techniques, 8, 11 (2015), 4863-4890.

29. Li R., Palm B. B., Ortega A. M., Hu W., Peng Z., Day D. A., Knote C., Brune W. H., de Gouw J., Jimenez J. L.* Modeling the radical chemistry in an Oxidation Flow Reactor (OFR): radical formation and recycling, sensitivities, and OH exposure estimation equation. Journal of Physical Chemistry A, 119, 19 (2015), 4418-4432.

30. Pernot P.*, Peng Z., Plessis S., Carrasco N. Dissociative recombination exalts molecular growth in N2/CH4 plasmas. EPJ Web of Conferences, 84 (2015), 06003.

31. Peng Z., Carrasco N., Pernot P.* Modeling of synchrotron-based laboratory simulations of Titan’s ionospheric photochemistry. GeoResJ, 1-2 (2014), 33-53.

32. Peng Z., Gautier T., Carrasco N.*, Pernot P., Giuliani A.*, Mahjoub A., Correia J.-J., Buch A., Bénilan Y., Szopa C., Cernogora G. Titan's atmosphere simulation experiment using continuum UV-VUV synchrotron radiation. Journal of Geophysical Research: Planets, 118, 4 (2013), 778-788.

33. Gans B., Peng Z., Carrasco N., Gauyacq D., Lebonnois S., Pernot P.* Impact of a new wavelength-dependent representation of methane photolysis branching ratios on the modeling of Titan's atmospheric photochemistry. Icarus, 223, 1 (2013), 330-343.

34. Gautier T.*, Peng Z., Giuliani A., Carrasco N., Cernogora G., Mahjoub A., Correia J.-J., Szopa C., Pernot P., Buch A., Bénilan Y. Photochemistry simulation of planetary atmosphere using synchrotron radiation at SOLEIL: Application to Titan's atmosphere. EAS Publications Series, 58 (2012), 199-203.

35. Peng Z., Cailliez F., Dobrijevic M., Pernot P.* Null Variance Altitudes for the photolysis rate constants of species with barometric distribution: Illustration on Titan upper atmosphere modeling. Icarus, 218, 2 (2012), 950-955.

36. Peng Z., Dobrijevic M., Hébrard E., Carrasco N., Pernot P.* Photochemical modeling of Titan atmosphere at the 10 percent uncertainty horizon. Faraday Discussions, 147 (2010), 137-153.

37. Li J., Song X., Peng Z., Hou H., Wang B.* Computational study of the reaction of CH2 (X3B1) with CH3OH. Journal of Physical Chemistry A, 112, 48 (2008), 12492-12497.

（二）軟件著作權

1. KinSim：一種大氣化學動力學模拟器

2. COVID-19 Aerosol Transmission Estimator

（三）獎勵

1. 2022年度Environmental Science & Technology最佳論文獎，2024

2. 2021年度Environmental Science & Technology Letters最佳論文獎，2022

3. 科羅拉多大學—美國國家大氣海洋管理局聯合環境科學研究所傑出貢獻獎（1/1），2022

4. Peter Salamon青年科學家獎，2014

如果你喜歡寫程序、有興趣讓大氣化學模型在化學上變得更智能，或者喜歡動手、有興趣搗鼓空氣淨化器，無論你是僅比我晚幾天加入暨大的新人，或者相對于我已經是“老”暨大人，都歡迎和我聯系。

我現在并沒有一個團隊。有你加入，我們就是一個團隊。