C. S. Zhao
Peking University
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Featured researches published by C. S. Zhao.
Atmospheric Chemistry and Physics | 2011
F. Yang; H. Xue; Z. Deng; C. S. Zhao; Qiang Zhang
Aerosol size distribution and cloud condensation nucleus (CCN) number concentration were measured in the North China Plain from 31 December 2009 to 20 January 2010. The CCN closure study was performed using these data and droplet kinetic condensational growth model. The calculated CCN concentration with the assumption of pure ammonium sulfate aerosol is 40–140 % higher than that observed for the supersaturations in this study. A sensitivity test on aerosol solubility and mixing state indicates that 0.2– 0.5 mass fraction of ammonium sulfate for internal mixture can lead to a ratio of 0.82–1.30 for the calculated to observed CCN concentrations, and that 0.4–0.7 mass fraction of ammonium sulfate for external mixture results in a ratio of 0.74– 1.25 in the North China Plain during the time period of the field observations, suggesting that a relatively simple scheme may be used for CCN prediction in climate models for this region. Finally, we compare the calculated CCN concentrations from the kinetic condensational growth model and the equilibrium model. The kinetic condensational growth model can simulate droplet growth in a time period under a certain supersaturation, while the equilibrium model only predicts whether a certain aerosol can be activated as CCN under that supersaturation. The CCN concentration calculated with the kinetic model is higher than that with the equilibrium model at supersaturations of 0.056 % and 0.083 %, because some particles that are not activated from the equilibrium pointof-view can grow large enough to be considered as CCN in the kinetic model. While at a supersaturation of 0.17 %, CCN concentration calculated with the kinetic model is lower than that with the equilibrium model, due to the limitation of droplet kinetic growth. The calculated CCN concentrations using the kinetic model and the equilibrium model are the same at supersaturations of 0.35 % and 0.70 %.
Atmospheric Chemistry and Physics | 2011
W. Y. Xu; C. S. Zhao; L. Ran; Z. Z. Deng; Pengfei Liu; N. Ma; Weili Lin; Xiaobin Xu; P. Yan; X. He; J. Yu; W. D. Liang; L. L. Chen
Atmospheric Chemistry and Physics | 2011
Pengfei Liu; C. S. Zhao; T. Göbel; E. Hallbauer; A. Nowak; L. Ran; W. Y. Xu; Z. Z. Deng; N. Ma; K. Mildenberger; S. Henning; Frank Stratmann; A. Wiedensohler
Atmospheric Chemistry and Physics | 2011
N. Ma; C. S. Zhao; A. Nowak; T. Müller; S. Pfeifer; Yafang Cheng; Z. Z. Deng; Pengfei Liu; W. Y. Xu; L. Ran; P. Yan; T. Göbel; E. Hallbauer; K. Mildenberger; S. Henning; J. Yu; L. L. Cheng; X. J. Zhou; Frank Stratmann; A. Wiedensohler
Atmospheric Chemistry and Physics | 2014
G. Q. Fu; W. Y. Xu; R. F. Yang; J. B. Li; C. S. Zhao
Atmospheric Chemistry and Physics | 2011
Z. Z. Deng; C. S. Zhao; N. Ma; Pengfei Liu; L. Ran; W. Y. Xu; J. Chen; Z. Liang; S. Liang; Mengyu Huang; Xincheng Ma; Qiang Zhang; J. N. Quan; P. Yan; S. Henning; K. Mildenberger; E. Sommerhage; M. Schäfer; Frank Stratmann; A. Wiedensohler
Atmospheric Chemistry and Physics | 2011
L. Ran; C. S. Zhao; W. Y. Xu; X. Q. Lu; M. Han; Weili Lin; P. Yan; Xiaobin Xu; Z. Z. Deng; N. Ma; Pengfei Liu; J. Yu; W. D. Liang; L. L. Chen
Atmospheric Chemistry and Physics | 2013
Hongjian Liu; C. S. Zhao; Bettina Nekat; N. Ma; A. Wiedensohler; D. van Pinxteren; Gerald Spindler; K. Müller; Hartmut Herrmann
Atmospheric Chemistry and Physics | 2011
N. Ma; C. S. Zhao; T. Müller; Yafang Cheng; Pengfei Liu; Z.Z. Deng; W. Y. Xu; L. Ran; Bettina Nekat; D. van Pinxteren; Thomas Gnauk; K. Müller; Hartmut Herrmann; P. Yan; X. J. Zhou; A. Wiedensohler
Atmospheric Chemistry and Physics | 2014
Yuxuan Bian; C. S. Zhao; N. Ma; J. Chen; W. Y. Xu
