Modeling Climate Changes and Atmospheric Ozone Variations from 1980 to 2020 Using the Chemistry-Climate Model SOCOLv3

IF 0.9 Q4 OPTICS

Atmospheric and Oceanic Optics Pub Date : 2024-09-05 DOI:10.1134/S1024856024700519

M. A. Usacheva, S. P. Smyshlyaev, E. V. Rozanov, B. A. Zubov

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Abstract

To assess the relative contribution of key chemical and physical processes to the observed variability in climate and atmospheric gas composition from the 1980s to the 2020s, numerical experiments were conducted using the chemical-climatic model SOCOLv3. The study investigated factors determining the variability of principal climatic characteristics, including changes in the concentrations of ozone-depleting substances; variations in greenhouse gas concentrations, sea surface temperature, and sea ice extent; fluctuations in solar activity; and alterations in atmospheric aerosol content. Calculations for scenarios considering each of these factors individually, as well as a baseline model experiment accounting for all factors concurrently, were performed to evaluate the relative roles of these factors. The outcomes of the numerical experiments determined the relative contributions of different factors to changes in tropospheric temperature, lower stratospheric temperature, and ozone content from 1980 to 2020. The results of the model calculations were then compared with data from SBUV satellite measurements.

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利用化学-气候模型 SOCOLv3 模拟 1980 年至 2020 年的气候变化和大气臭氧变化

摘要为了评估关键化学和物理过程对观测到的 20 世纪 80 年代至 2020 年代气候和大气气体成分变化的相对贡献，使用化学-气候模型 SOCOLv3 进行了数值实验。研究调查了决定主要气候特征变化的因素，包括臭氧消耗物质浓度的变化；温室气体浓度、海面温度和海冰范围的变化；太阳活动的波动；以及大气气溶胶含量的变化。为评估这些因素的相对作用，分别对这些因素进行了计算，并对同时考虑所有因素的基线模型实验进行了计算。数值实验结果确定了不同因素对 1980 年至 2020 年对流层温度、低平流层温度和臭氧含量变化的相对贡献。然后将模型计算结果与 SBUV 卫星测量数据进行了比较。

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来源期刊

Atmospheric and Oceanic Optics OPTICS-

CiteScore

2.40

自引率

42.90%

发文量

期刊介绍： Atmospheric and Oceanic Optics is an international peer reviewed journal that presents experimental and theoretical articles relevant to a wide range of problems of atmospheric and oceanic optics, ecology, and climate. The journal coverage includes: scattering and transfer of optical waves, spectroscopy of atmospheric gases, turbulent and nonlinear optical phenomena, adaptive optics, remote (ground-based, airborne, and spaceborne) sensing of the atmosphere and the surface, methods for solving of inverse problems, new equipment for optical investigations, development of computer programs and databases for optical studies. Thematic issues are devoted to the studies of atmospheric ozone, adaptive, nonlinear, and coherent optics, regional climate and environmental monitoring, and other subjects.