蔡潤龍

2010年—2014年，蔡潤龍就讀於清華大學環境學院，畢業並獲得學士學位。

2014年—2019年，就讀於清華大學環境學院，畢業並獲得博士學位。

2019年9月—2023年11月，在芬蘭赫爾辛基大學大氣與地球系統科學研究院從事博士後研究工作。

2020年，獲得芬蘭科學院博士後人才計畫資助。

2023年11月，擔任復旦大學環境科學與工程系青年研究員；同年，獲得上海市白玉蘭人才計畫青年項目資助。

蔡潤龍的研究包括：結合前沿方法的開發對納米氣溶膠和前體物的理化性質進行線上表征，進而研究其形成轉化機制和環境氣候影響。

Cai R, Yin R, Li X, et al. Significant contributions of trimethylamine to sulfuric acid nucleation in polluted environments[J]. npj Climate and Atmospheric Science, 2023, 6(1): 75.

Stolzenburg D, Cai R, Blichner S M, et al. Atmospheric nanoparticle growth[J]. Reviews of Modern Physics, 2023, 95(4): 045002.

Cai R, Deng C, Stolzenburg D, et al. Survival probability of new atmospheric particles: closure between theory and measurements from 1.4 to 100 nm[J]. Atmospheric Chemistry and Physics, 2022, 22(22): 14571-14587.

Cai R, Huang W, Meder M, et al. Improving the Sensitivity of Fourier Transform Mass Spectrometer (Orbitrap) for Online Measurements of Atmospheric Vapors[J]. Analytical Chemistry, 2022, 94(45): 15746-15753.

Cai R, Yin R, Yan C, et al. The missing base molecules in atmospheric acid–base nucleation[J]. National science review, 2022, 9(10): nwac137.

Cai R, Häkkinen E, Yan C, et al. The effectiveness of the coagulation sink of 3–10 nm atmospheric particles[J]. Atmospheric Chemistry and Physics, 2022, 22(17): 11529-11541.

Cai R, Kangasluoma J. The proper view of cluster free energy in nucleation theories[J]. Aerosol Science and Technology, 2022, 56(8): 757-766.

Cai R, Yan C, Yang D, et al. Sulfuric acid–amine nucleation in urban Beijing[J]. Atmospheric Chemistry and Physics, 2021, 21(4): 2457-2468.

Cai R, Yan C, Worsnop D R, et al. An indicator for sulfuric acid–amine nucleation in atmospheric environments[J]. Aerosol Science and Technology, 2021, 55(9): 1059-1069.

Cai R, Li Y, Clément Y, et al. Orbitool: a software tool for analyzing online Orbitrap mass spectrometry data[J]. Atmospheric Measurement Techniques Discussions, 2020, 2020: 1-23.

Cai R, Li C, He X C, et al. Impacts of coagulation on the appearance time method for new particle growth rate evaluation and their corrections[J]. Atmospheric Chemistry and Physics, 2021, 21(3): 2287-2304.

Li C, Cai R. Tutorial: The discrete-sectional method to simulate an evolving aerosol[J]. Journal of Aerosol Science, 2020, 150: 105615.

Cai R, Zhou Y, Jiang J. Transmission of charged nanoparticles through the DMA adverse axial electric field and its improvement[J]. Aerosol Science and Technology, 2020, 54(1): 21-32.

Cai R, Jiang J. Models for estimating nanoparticle transmission efficiency through an adverse axial electric field[J]. Aerosol Science and Technology, 2020, 54(3): 332-341.

Cai R, Jiang J, Mirme S, et al. Parameters governing the performance of electrical mobility spectrometers for measuring sub-3 nm particles[J]. Journal of Aerosol Science, 2019, 127: 102-115.

Cai R, Yang D, Ahonen L R, et al. Data inversion methods to determine sub-3 nm aerosol size distributions using the particle size magnifier[J]. Atmospheric Measurement Techniques, 2018, 11(7): 4477-4491.

Cai R, Chandra I, Yang D, et al. Estimating the influence of transport on aerosol size distributions during new particle formation events[J]. Atmospheric Chemistry and Physics, 2018, 18(22): 16587-16599.

Cai R, Attoui M, Jiang J, et al. Characterization of a high-resolution supercritical differential mobility analyzer at reduced flow rates[J]. Aerosol Science and Technology, 2018, 52(11): 1332-1343.

Cai R, Yang D, Fu Y, et al. Aerosol surface area concentration: a governing factor in new particle formation in Beijing[J]. Atmospheric Chemistry and Physics, 2017, 17(20): 12327-12340.

Cai R, Jiang J. A new balance formula to estimate new particle formation rate: reevaluating the effect of coagulation scavenging[J]. Atmospheric Chemistry and Physics, 2017, 17(20): 12659-12675.

Cai R, Chen D R, Hao J, et al. A miniature cylindrical differential mobility analyzer for sub-3 nm particle sizing[J]. Journal of Aerosol Science, 2017, 106: 111-119.