部门排放对印度次大陆人为气溶胶情景的贡献以及减缓对空气质量、气候和健康的影响

IF 1.2 4区地球科学 Q4 ENVIRONMENTAL SCIENCES

Climate Research Pub Date : 2021-10-21 DOI:10.3354/cr01671

P. Ajay, Binita Pathak, P. Bhuyan, F. Solmon, F. Giorgi

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引用次数: 2

摘要

在过去的几十年里，印度的部门人为排放发生了重大变化，改变了该地区的空气质量和辐射收支。然而，人们对这些部门的贡献仍然知之甚少。本研究试图利用RegCM4.4区域气候模式和温室气体-空气污染相互作用和协同效应(GAINS)全球模式估算印度次大陆不同部门的人为气溶胶和二氧化硫排放及其对区域气候和人类健康的影响。我们考虑目前的排放量以及2030年减排情景下的排放量。以ECLIPSE v5a为排放清单的2000年和2015年RegCM模拟显示，能源部门的SO2排放量很高，这在很大程度上促进了人为气溶胶光学深度(AODanthro)和气候强迫。与2000年相比，2015年住宅和交通部门对气候强迫的影响有所增加。在减缓情景下，印度-恒河平原的高AODanthro(0.35-0.45)发生日数大幅减少5-10%。特别是在印度的5个特大城市(德里、加尔各答、孟买、金奈和班加罗尔)，黑碳、有机碳和直径≤2.5微米的颗粒物(PM2.5)的浓度在减缓情景下大幅降低;然而，SO2增加。减少污染物有助于大大减少所有城市的预期寿命损失。本研究主张未来有必要制定空气质量与气候变化之间协同作用的排放控制政策。

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Sectoral emissions contributions to anthropogenic aerosol scenarios over the Indian subcontinent and effects of mitigation on air quality, climate, and health

Over the last few decades, there have been substantial changes in sectoral anthropogenic emissions over India, modifying the region’s air quality and radiation budget. However, these sectoral contributions are still poorly understood. This study attempts to estimate the anthropogenic aerosols and SO2 emissions from different sectors over the Indian subcontinent and their implications for regional climate and human health using the RegCM4.4 regional climate model and the Greenhouse Gas-Air Pollution Interactions and Synergies (GAINS) global model. We consider current emissions as well as emissions with a mitigation scenario for the year 2030. The RegCM simulations with ECLIPSE v5a as emissions inventory for 2000 and 2015 show high SO2 emissions from the energy sector, substantially contributing to anthropogenic aerosol optical depth (AODanthro) and climate forcing. The residential and transport sectors’ imprint on climate forcing is increased in 2015 compared to 2000. Higher AODanthro (0.35-0.45) occurrence days substantially decrease under a mitigation scenario by 5-10% over the Indo-Gangetic Plain. In particular, over 5�megacities (Delhi, Kolkata, Mumbai, Chennai, and Bangalore) of India, the concentrations of black carbon, organic carbon, and particulate matter ≤2.5 µm in diameter (PM2.5) are substantially reduced under the mitigation scenario; however, SO2 is increased. The reduction of pollutants contributes to significantly reducing life expectancy loss in all cities. This study advocates the need for future emission control policies with a synergy between air quality and climate change.

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来源期刊

Climate Research 地学-环境科学

CiteScore

2.90

自引率

9.10%

发文量

审稿时长

3 months

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