Synergic Benefits of Air Pollutant Reduction, CO2 Emission Abatement, and Water Saving under the Goal of Achieving Carbon Emission Peak: The Case of Tangshan City, China

The study aims to explore the synergic benefits of reducing air pollutants and CO2 and water consumption under the carbon emission peak (CEP) policies at a city level. Air pollutants and CO2 emissions are predicted by the Low Emissions Analysis Platform (LEAP) model, and the water consumption is for...

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Veröffentlicht in:	International journal of environmental research and public health 2022-06, Vol.19 (12), p.7145
Hauptverfasser:	Yang, Rupu, Wang, Min, Zhao, Mengxue, Feng, Xiangzhao
Format:	Artikel
Sprache:	eng
Schlagworte:	Air pollution Carbon Carbon dioxide Cities Climate change Electricity Emission analysis Emission standards Emissions Energy consumption Greenhouse gases Industrial plant emissions Investigations Particulate matter Pollutants Pollution control Steel industry Sulfur dioxide Transportation industry VOCs Volatile organic compounds Water conservation Water consumption
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container_title	International journal of environmental research and public health
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creator	Yang, Rupu Wang, Min Zhao, Mengxue Feng, Xiangzhao
description	The study aims to explore the synergic benefits of reducing air pollutants and CO2 and water consumption under the carbon emission peak (CEP) policies at a city level. Air pollutants and CO2 emissions are predicted by the Low Emissions Analysis Platform (LEAP) model, and the water consumption is forecast by the quota method. Two scenarios are constructed with the same policies, but to different degrees: the reference scenario achieves CEP in 2030, and the green and low carbon scenario achieves CEP in 2025. The prediction results show that air pollutant emissions, CO2 emissions, and water consumption can be obviously decreased by intensifying the CEP policies. The synergic abatement effect was illustrated by the synergic reduction curve. Accelerating the adjustment of economic structure saves the most water, reduces the greatest amount of CO2 emission, and also obtains the best synergic reduction capability between water consumption and CO2 emission. Transforming the traditionally long process of steelmaking toward a short electric process reduces the majority of PM2.5, SO2, and VOC emissions, while consuming more water. The study provides a new viewpoint to assess and optimize the CEP action plan at city levels.
doi_str_mv	10.3390/ijerph19127145
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subjects	Air pollution Carbon Carbon dioxide Cities Climate change Electricity Emission analysis Emission standards Emissions Energy consumption Greenhouse gases Industrial plant emissions Investigations Particulate matter Pollutants Pollution control Steel industry Sulfur dioxide Transportation industry VOCs Volatile organic compounds Water conservation Water consumption
title	Synergic Benefits of Air Pollutant Reduction, CO2 Emission Abatement, and Water Saving under the Goal of Achieving Carbon Emission Peak: The Case of Tangshan City, China
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