JpGU-AGU Joint Meeting 2020

Presentation information

[E] Poster

A (Atmospheric and Hydrospheric Sciences ) » A-AS Atmospheric Sciences, Meteorology & Atmospheric Environment

[A-AS01] High performance computing for next generation weather, climate, and environmental sciences

convener:Hiromu Seko(Meteorological Research Institute), Takemasa Miyoshi(RIKEN), Chihiro Kodama(Japan Agency for Marine-Earth Science and Technology), Masayuki Takigawa(Japan Agency for Marine-Earth Science and Technology)

[AAS01-P06] Retrieval of hygroscopic growth factor of uniformly mixed aerosol particles based on immune evolution algorithm

*Zhicha Zhang1,2, Changjian Ni1,2 (1.Chengdu University of Information Technology, 2.Plateau Atmospheres and Environment Key Laboratory of Sichuan Province)

Keywords: aerosol, Mie scattering theory, hygroscopic growth factor, retrieval, immune evolution algorithm

Based on decomposition of atmospheric extinction coefficient and Mie scattering theory, the objective function, which has the sole variable of the hygroscopic growth factor of uniformly mixed aerosol particles, was established. Furthermore, immune evolution algorithm was further used to optimize the objective function, and a feasible method was proposed to retrieve hygroscopic growth factor of uniformly mixed aerosol particles. The performance of the method was evaluated by utilizing the hourly ground observation data from nephelometer, aethalometer and GRIMM180 environment particle monitor in Chengdu from October 2017 to December 2017, as well as the coincidental environmental and meteorological data, which includes atmospheric visibility, relative humidity (RH) and NO2 mass concentration. The results suggest that the retrieval algorithm is characterized by fast convergence, robustness and precision for all tested samples. hygroscopic growth model of uniformly mixed aerosol particles was established during autumn and winter in Chengdu. Note that this model could significantly improve the simulation accuracy of aerosol scattering coefficient in ambient conditions. The advantage of this model is that the average relative error between the simulated and the measured is only 12.7%. The universal algorithm is beneficial for subsequent study on the aerosol hygroscopic properties and its radiative forcing impacts.