Contributing to local policy making on GHG emission reduction through inventorying and attribution: A case study of Shenyang, China

Cities consumed 84% of commercial energy in China, which indicates cities should be the main areas for GHG emissions reduction. Our case study of Shenyang in this paper shows how a clear inventory analysis on GHG emissions at city level can help to identify the major industries and societal sectors...

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Veröffentlicht in:	Energy policy 2011-10, Vol.39 (10), p.5999-6010
Hauptverfasser:	Xi, Fengming, Geng, Yong, Chen, Xudong, Zhang, Yunsong, Wang, Xinbei, Xue, Bing, Dong, Huijuan, Liu, Zhu, Ren, Wanxia, Fujita, Tsuyoshi, Zhu, Qinghua
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Sprache:	eng
Schlagworte:	Air pollution Air pollution caused by fuel industries Applied sciences Atmospheric pollution Boundaries Carbon carbon dioxide Carbon emissions Case studies China China (People's Republic) cities City GHG emission inventory Combustion and energy production Commerce construction industry Decision making Electric power electricity Emission analysis Emission attribution Emissions control Energy Energy consumption Energy efficiency Energy industry Energy policy Energy sector Energy. Thermal use of fuels Exact sciences and technology General. Regulations. Norms. Economy Global warming Greenhouse effect greenhouse gas emissions Greenhouse gases Greenhouse gases City GHG emission inventory Emission attribution heat Industrial districts Inventories issues and policy Local government manufacturing Metering. Control Pollution Pollution sources. Measurement results Reduction Shenyang Stockpiling Studies system boundary
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container_end_page	6010
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container_title	Energy policy
container_volume	39
creator	Xi, Fengming Geng, Yong Chen, Xudong Zhang, Yunsong Wang, Xinbei Xue, Bing Dong, Huijuan Liu, Zhu Ren, Wanxia Fujita, Tsuyoshi Zhu, Qinghua
description	Cities consumed 84% of commercial energy in China, which indicates cities should be the main areas for GHG emissions reduction. Our case study of Shenyang in this paper shows how a clear inventory analysis on GHG emissions at city level can help to identify the major industries and societal sectors for reduction efforts so as to facilitate low-carbon policy-making. The results showed total carbon emission in 2007 was 57 Mt CO 2 equivalents (CO 2e), of which 41 Mt CO 2e was in-boundary emissions and 16 Mt CO 2e was out-of-boundary emissions. The energy sector was dominant in the emission inventory, accounting for 93.1% of total emissions. Within energy sector, emissions from energy production industry, manufacturing and construction industry accounted for 88.4% of this sector. Our analysis showed that comparing with geographical boundary, setting system boundary based on single process standard could provide better information to decision makers for carbon emission reduction. After attributing electricity and heating consumption to final users, the resident and commercial sector became the largest emitter, accounting for 28.5% of total emissions. Spatial analysis of emissions showed that industrial districts such as Shenbei and Tiexi had the large potential to reduce their carbon emissions. Implications of results are finally discussed. ► An inventory analysis can help identify key industries and societal sectors for reduction efforts. ► Setting system boundary can provide better information for carbon emission reduction. ► Urban districts with heavy industrial plants have potential to reduce their carbon emissions. ► Policies that support urban energy structure optimization can accelerate low-carbon development.
doi_str_mv	10.1016/j.enpol.2011.06.063
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After attributing electricity and heating consumption to final users, the resident and commercial sector became the largest emitter, accounting for 28.5% of total emissions. Spatial analysis of emissions showed that industrial districts such as Shenbei and Tiexi had the large potential to reduce their carbon emissions. 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Our case study of Shenyang in this paper shows how a clear inventory analysis on GHG emissions at city level can help to identify the major industries and societal sectors for reduction efforts so as to facilitate low-carbon policy-making. The results showed total carbon emission in 2007 was 57 Mt CO 2 equivalents (CO 2e), of which 41 Mt CO 2e was in-boundary emissions and 16 Mt CO 2e was out-of-boundary emissions. The energy sector was dominant in the emission inventory, accounting for 93.1% of total emissions. Within energy sector, emissions from energy production industry, manufacturing and construction industry accounted for 88.4% of this sector. Our analysis showed that comparing with geographical boundary, setting system boundary based on single process standard could provide better information to decision makers for carbon emission reduction. After attributing electricity and heating consumption to final users, the resident and commercial sector became the largest emitter, accounting for 28.5% of total emissions. Spatial analysis of emissions showed that industrial districts such as Shenbei and Tiexi had the large potential to reduce their carbon emissions. Implications of results are finally discussed. ► An inventory analysis can help identify key industries and societal sectors for reduction efforts. ► Setting system boundary can provide better information for carbon emission reduction. ► Urban districts with heavy industrial plants have potential to reduce their carbon emissions. ► Policies that support urban energy structure optimization can accelerate low-carbon development.</description><subject>Air pollution</subject><subject>Air pollution caused by fuel industries</subject><subject>Applied sciences</subject><subject>Atmospheric pollution</subject><subject>Boundaries</subject><subject>Carbon</subject><subject>carbon dioxide</subject><subject>Carbon emissions</subject><subject>Case studies</subject><subject>China</subject><subject>China (People's Republic)</subject><subject>cities</subject><subject>City GHG emission inventory</subject><subject>Combustion and energy production</subject><subject>Commerce</subject><subject>construction industry</subject><subject>Decision making</subject><subject>Electric power</subject><subject>electricity</subject><subject>Emission analysis</subject><subject>Emission attribution</subject><subject>Emissions control</subject><subject>Energy</subject><subject>Energy consumption</subject><subject>Energy efficiency</subject><subject>Energy industry</subject><subject>Energy policy</subject><subject>Energy sector</subject><subject>Energy. 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Our case study of Shenyang in this paper shows how a clear inventory analysis on GHG emissions at city level can help to identify the major industries and societal sectors for reduction efforts so as to facilitate low-carbon policy-making. The results showed total carbon emission in 2007 was 57 Mt CO 2 equivalents (CO 2e), of which 41 Mt CO 2e was in-boundary emissions and 16 Mt CO 2e was out-of-boundary emissions. The energy sector was dominant in the emission inventory, accounting for 93.1% of total emissions. Within energy sector, emissions from energy production industry, manufacturing and construction industry accounted for 88.4% of this sector. Our analysis showed that comparing with geographical boundary, setting system boundary based on single process standard could provide better information to decision makers for carbon emission reduction. After attributing electricity and heating consumption to final users, the resident and commercial sector became the largest emitter, accounting for 28.5% of total emissions. Spatial analysis of emissions showed that industrial districts such as Shenbei and Tiexi had the large potential to reduce their carbon emissions. Implications of results are finally discussed. ► An inventory analysis can help identify key industries and societal sectors for reduction efforts. ► Setting system boundary can provide better information for carbon emission reduction. ► Urban districts with heavy industrial plants have potential to reduce their carbon emissions. ► Policies that support urban energy structure optimization can accelerate low-carbon development.</abstract><cop>Kidlington</cop><pub>Elsevier Ltd</pub><doi>10.1016/j.enpol.2011.06.063</doi><tpages>12</tpages></addata></record>
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subjects	Air pollution Air pollution caused by fuel industries Applied sciences Atmospheric pollution Boundaries Carbon carbon dioxide Carbon emissions Case studies China China (People's Republic) cities City GHG emission inventory Combustion and energy production Commerce construction industry Decision making Electric power electricity Emission analysis Emission attribution Emissions control Energy Energy consumption Energy efficiency Energy industry Energy policy Energy sector Energy. Thermal use of fuels Exact sciences and technology General. Regulations. Norms. Economy Global warming Greenhouse effect greenhouse gas emissions Greenhouse gases Greenhouse gases City GHG emission inventory Emission attribution heat Industrial districts Inventories issues and policy Local government manufacturing Metering. Control Pollution Pollution sources. Measurement results Reduction Shenyang Stockpiling Studies system boundary
title	Contributing to local policy making on GHG emission reduction through inventorying and attribution: A case study of Shenyang, China
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