云南省城市生活垃圾处理温室气体排放特征

根据《IPCC国家温室气体清单指南》和《省级温室气体清单编制指南》方法,建立2018年云南省16个州(市)城市生活垃圾处理温室气体排放清单,包括生活垃圾填埋和焚烧处理过程,并分析了温室气体排放的时间分布、空间分布和影响因素等。结果表明;(1)2018年云南省生活垃圾处理温室气体总排放量为536万t CO_2当量,各州(市)间排放量差异明显,滇中经济发达地区和滇东北人口密度较高地区排放量明显高于滇西北地区。(2)2005—2018年,云南省生活垃圾处理排放的温室气体量增长了191.3%,温室气体排放组成发生明显变化,CH4比重不断下降,CO_2比重不断增加。(3)城镇人口数量、生活垃圾处理量、经济发展水平与温室气体排放量显著相关,其中人口数量更为明显。     

丝绸之路经济带西南四省区温室气体排放核算及等级评估

为建设绿色丝绸之路提供决策参考,基于IPCC法和中国《省级温室气体编制指南》,核算了四川、重庆、云南、广西四省区的温室气体排放清单,并进行了动态分析和排放等级评估。结果表明:2000～2013年四省区温室气体排放总量呈快速增长趋势,其中CO_2排放比例最高,其次是N_2O和CH_4。能源消费是温室气体排放的主要来源,其中又以煤炭贡献量最大。林业固碳的增长速度赶不上温室气体排放的增长速度,且林业固碳能力增长不明显。人均和单位面积温室气体排放量均呈不断增长趋势,且高于全球承担减排义务与应对气候变化的目标,减排任务仍然非常艰巨。四省区GHG排放指数均呈不断增长趋势,排放等级四川、云南和广西均由较低(Ⅰc)上升为中下(Ⅱa);重庆由中下(Ⅱa)上升为较高(Ⅲa)。     

锦州市2015年二氧化硫新增量预测

根据《“十二五”主要污染物总量控制规划编制技术指南》提供的公式,预测社会经济发展主要参数,包括GDP、能源消费总量、煤炭消费量等指标。二氧化硫新增量预测以宏观测算方法为主,并按行业测算方法予以校核。宏观测算分为火电行业和非电力行业,结果为1.419万t;分行业预测分为石化、建材（水泥）、有色、冶金和其他行业,结果为1.774万t,两者预测偏差为25%,采用分行业预测结果作为2015年二氧化硫新增量预测。     

油气田温室气体清单编制的作法

从温室气体统计边界确定、活动水平数据收集、排放量统计到编制形成石油企业需要的温室气体清单,介绍了石油企业温室气体清单编制中,做好编制工作的一些做法,为石油企业实现温室气体减排和控制工作奠定基础。     

加拿大油气系统温室气体逃逸排放清单简述

油气系统温室气体逃逸排放是温室气体排放清单的重要组成部分。加拿大在清单中统一考虑了油气系统可能存在的温室气体排放源,因此清单中不仅包括了温室气体的逃逸排放(泄漏、排空),还考虑了能源燃烧中的气体排放,所考虑的温室气体种类既包括甲烷,也包括二氧化碳。采用的是政府间气候变化专门委员会(IPCC)第三层次方法(Tier3),即设备清单法、操作时间法和活动水平法三种计算方法,详细地将排放源分类进行估算。该国对数据的管理、质量控制和质量评估、不确定性分析以及在如何保证数据的持续性方面的作法都值得我们学习和借鉴。     

焦化企业温室气体排放核算方法实例解析

气候变化问题已成为人类面临的共同挑战。2013年以来,我国陆续发布了24个行业企业温室气体排放核算方法与报告指南(试行),焦化行业是其中之一。文章按照焦化行业《指南》实际测算了某焦化企业温室气体排放情况,并对核算过程中遇到的问题进行了分析,为焦化企业碳资产管理给出了合理意见。     

石油石化企业温室气体清单编制简析

文章通过简要阐述石油石化企业温室气体清单的编制全过程,确定石油石化企业温室气体排放种类、识别主要温室气体排放源、列举重点生产过程中温室气体排放量的核算方法,为石油石化企业实现温室气体减排和控制工作、为完成国务院规定的到2020年我国单位国内生产总值二氧化碳排放强度比2005年下降40%~45%的约束性指标,奠定数据理论基础。     

《大气污染防治行动计划》实施环境效果模拟

本研究利用2010年污染源普查数据和MEIC排放清单建立全国大气污染物高时空分辨率排放清单,在此基础上利用2012年环境统计数据对其进行修订建立2012年全国大气污染物高时空分辨率排放清单;结合《大气污染防治行动计划》(以下简称《计划》)研究工作,测算了《计划》实施后在污染源综合治理、落后产能淘汰、能源结构调整方面对SO2、NOx、颗粒物、VOCs的减排量,同时对污染物新增量进行了预测,建立了《计划》实施后全国大气污染物高时空分辨率排放清单;利用CMAQ空气质量模型模拟分析了《计划》实施的空气质量改善效果。结果表明:《计划》实施后,将可以减少641万吨SO2、859万吨NOx、547万吨颗粒物(不含扬尘污染控制)、627万吨VOCs,全国、京津冀、长三角及珠三角区域PM2.5年均浓度将分别比2012年下降22.08%、33.99%、23.98%、24.04%。如果《计划》要求全部落实,可以实现空气质量改善目标。     

石油石化行业温室气体清单编制研究进展

石油化工生产企业是高耗能企业,也是温室气体排放主要来源之一,温室气体排放统计、计算与监测可为参与碳交易提供基础信息,促进石油化工生产企业可持续发展并实现减排目标。文章介绍了国内外认知度较高的温室气体核算标准,并对目前国内外已发布实施的石油石化行业清单编制标准进行归纳和比较。在此基础上提出了石油石化行业完善温室气体清单编制标准、加强温室气体排放核查工作、建立温室气体统计和管理体系等建议措施。     

温室气体排放核算与报告平台研究与应用

为适应国家对全国碳排放权交易市场的工作目标及工作要求,根据国家政策及集团公司需求,中国石油天然气集团公司编制了《中国石油天然气集团公司温室气体排放核算与报告工作方案》,设计开发了集团公司温室气体排放核算与报告平台。文章分析了温室气体排放核算和报告四大步的工作流程;根据中国石油集团公司温室气体核算工作方案的工作要求,对难点进行分析:核算边界差异较大、基础数据来源分散、数据填报量及核算量庞大。阐述了核算系统的设计思路及系统构架、主要功能,并介绍了系统的应用情况。     

Greenhouse gas emissions along the rural-urban gradient

This paper investigates how land use relates to greenhouse gas emissions, using data sources that are readily available to municipal planners. It presents a causal framework linking settlement patterns to greenhouse gas emissions via landscape impacts (deforestation, carbon sequestration by soils and plants, urban heat island), infrastructure impacts (transportation-related emissions, waste management-related emissions, electric transmission and distribution losses) and buildings (residential, commercial). This is not a full accounting because it does not include impacts from industrial activities, agriculture and consumer behavior not related to land use, such as food consumption and air travel. Exploratory case studies of municipalities lying along a gradient of increasing population density suggest that per-capita carbon dioxide emissions vary widely, following an inverted ‘U’ shape, with post-war suburbs riding the pinnacle. Reflecting their central regional roles, municipalities with good jobs-to-housing ratios have higher per-capita emissions because they host both residential and commercial buildings. Buildings typically contribute more emissions than personal transportation. Vehicle-miles traveled per capita shrink most dramatically at very high population densities and where transit options exist. Changing land-use patterns is a political challenge because localism and outdated zoning ordinances subvert regional solutions. Technical fixes, especially green buildings, must be part of the solution.     

Waste Management and Climate Change

Waste management has at least five types of impacts on climate change, attributable to: (1) landfill methane emissions; (2) reduction in industrial energy use and emissions due to recycling and waste reduction; (3) energy recovery from waste; (4) carbon sequestration in forests due to decreased demand for virgin paper; and (5) energy used in long-distance transport of waste: A recent USEPA study provides estimates of overall per-tonne greenhouse gas reductions due to recycling. Plausible calculations using these estimates suggest that countries such as the US or Australia could realise substantial greenhouse gas reductions through increased recycling, particularly of paper.     

Waste Management and Climate Change

Waste management has at least five types of impacts on climate change, attributable to: (1) landfill methane emissions; (2) reduction in industrial energy use and emissions due to recycling and waste reduction; (3) energy recovery from waste; (4) carbon sequestration in forests due to decreased demand for virgin paper; and (5) energy used in long-distance transport of waste: A recent USEPA study provides estimates of overall per-tonne greenhouse gas reductions due to recycling. Plausible calculations using these estimates suggest that countries such as the US or Australia could realise substantial greenhouse gas reductions through increased recycling, particularly of paper.     

Assessment of the greenhouse effect impact of technologies used for energy recovery from municipal waste: A case for England

Waste management activities contribute to global greenhouse gas emissions approximately by 4%. In particular the disposal of waste in landfills generates methane that has high global warming potential. Effective mitigation of greenhouse gas emissions is important and could provide environmental benefits and sustainable development, as well as reduce adverse impacts on public health. The European and UK waste policy force sustainable waste management and especially diversion from landfill, through reduction, reuse, recycling and composting, and recovery of value from waste. Energy from waste is a waste management option that could provide diversion from landfill and at the same time save a significant amount of greenhouse gas emissions, since it recovers energy from waste which usually replaces an equivalent amount of energy generated from fossil fuels. Energy from waste is a wide definition and includes technologies such as incineration of waste with energy recovery, or combustion of waste-derived fuels for energy production or advanced thermal treatment of waste with technologies such as gasification and pyrolysis, with energy recovery. The present study assessed the greenhouse gas emission impacts of three technologies that could be used for the treatment of Municipal Solid Waste in order to recover energy from it. These technologies are Mass Burn Incineration with energy recovery, Mechanical Biological Treatment via bio-drying and Mechanical Heat Treatment, which is a relatively new and uninvestigated method, compared to the other two. Mechanical Biological Treatment and Mechanical Heat Treatment can turn Municipal Solid Waste into Solid Recovered Fuel that could be combusted for energy production or replace other fuels in various industrial processes. The analysis showed that performance of these two technologies depends strongly on the final use of the produced fuel and they could produce GHG emissions savings only when there is end market for the fuel. On the other hand Mass Burn Incineration generates greenhouse gas emission savings when it recovers electricity and heat. Moreover the study found that the expected increase on the amount of Municipal Solid Waste treated for energy recovery in England by 2020 could save greenhouse gas emission, if certain Energy from Waste technologies would be applied, under certain conditions.     

Implications of Land Use Changes on Carbon Dynamics and Sequestration—Evaluation from Forestry Datasets, India

Forests and soils are a major sink of carbon, and land use changes can affect the magnitude of above ground and below ground carbon stores and the net flux of carbon between the land and the atmosphere. Studies on methods for examining the future consequences of changes in patterns of land use change and carbon flux gains importance, as they provide different options for CO₂ mitigation strategies. In this study, a simulation approach combining Markov chain processes and carbon pools for forests and soils has been implemented to study the carbon flows over a period of time. Markov chains have been computed by converting the land use change and forestry data of India from 1997 to 1999 into a matrix of conditional probabilities reflecting the changes from one class at time t to another class time t+1. Results from Markov modeling suggested Indian forests as a potential sink for 0.94 Gt carbon, with an increase in dense forest area of about 75.93 Mha and decrease of about 3.4 Mha and 5.0 Mha in open and scrub forests, if similar land use changes that occurred during 1997–1999 would continue. The limiting probabilities suggested 34.27 percent as dense forest, 6.90 as open forest, 0.4 percent mangrove forest, 0.1 percent scrub and 58 percent as non-forest area. Although Indian forests are found to be a potential carbon sink, analysis of results from transition probabilities for different years till 2050 suggests that, the forests will continue to be a source of about 20.59 MtC to the atmosphere. The implications of these results in the context of increasing anthropogenic pressure on open and scrub forests and their contribution to carbon source from land use change and forestry sector are discussed. Some of the mitigation aspects to reduce greenhouse gas emissions from land use change and forestry sector in India are also reviewed in the study.     

环渤海地区碳排放影响因素分解及其差异研究

在Kaya公式的基础上对环渤海地区碳排放影响因素进行了分解,并对各省市碳排放状况进行了对比分析。结果发现,环渤海地区碳排放量大致呈现持续均匀的增长趋势。其碳排放主要受能源结构、碳排放系数、能源强度、产业结构、经济规模5个因素影响。各省市碳排放量均呈加速增长趋势,能源结构仍以煤炭为主,产业结构有待优化。结合研究结果,从加强低碳技术创新、优化能源消费结构、开发绿色能源、宣传低碳观念角度提出了相关碳减排建议。     

宁夏能源结构的低碳优化研究

宁夏的经济结构具有显著的高碳特征，煤炭与电力行业占全区工业产值的比重约1／2，工业产值又占据宁夏GDP的半壁江山。低碳时代的到来不可逆转，减碳是对宁夏经济的重大考验与挑战。采用灰色关联分析法对宁夏各行业与碳排放的关联度进行分析，并结合各相关产业区域专业化系数分析，提出宁夏产业结构升级和能源结构优化的建议。     

我国发展低碳农业的主要措施研究

在全球气候变暖和能源危机的背景下,农业是温室气体主要排放源之一,低碳农业作为应对气候变化的农业行动,越来越受到人们的重视。低碳农业的目标是减缓温室气体,实现高效率、低能耗、低排放、高碳汇的高效农业。在推动我国低碳农业发展的措施方面,总结起来主要包括减少碳排放、增加碳汇和采用其他相应的技术措施相结合。也就是通过一系列相应的技术措施和基础设施建设,减少温室气体总量排放的同时,增加耕地、草地和林地吸收二氧化碳的量,从而实现低碳农业的可持续发展。     

碳达峰碳中和目标下固体废物治理的法律因应

我国在联合国大会上提出了“2030年碳达峰2060年碳中和”的目标。为达成此目标,固体废物治理领域也需要积极作出响应。固体废物治理体系的核心是固体废物的处置。不同的固体废物处置方式有着不同的碳排放结果,填埋或焚烧方式处置所排放的温室气体量都远大于循环利用的方式。应以固体废物领域碳排放统一核算制度为基石,从推进政策实施和立法修改等的多个层面上去因应。立法面向上,《固体废物污染环境防治法》《清洁生产促进法》《循环经济促进法》乃至编纂中的“环境法典”都应当围绕减碳模式的固体废物处置方式改进和制定相关法律规范;制度建设面向上,以固体废物碳排放强制核算法律制度建设为主,通过碳排放强制核算制度规范相关主体及其权利义务关系并深度挖掘固体废物处置的碳减排潜力。     

Carbon sequestration potential in reclaimed mine sites in seven east-central states

Terrestrial systems represent a significant potential carbon (C) sink to help mitigate or offset greenhouse gas emissions. Nearly 3.2 Mha are permitted for mining activities in the United States, which are required to be reclaimed with vegetative cover. While site-specific studies have assessed C accumulation on reclaimed mine sites, regional analyses to estimate potential C increases have not been conducted. For this analysis, potential C sequestration is analyzed on 567,000 ha of mine land in a seven-state region reclaimed to cropland, pasture, or forest. Carbon accumulation is estimated for cropland, pasture, and forest soils, forest litter layer, and aboveground biomass by estimating average annual rates of C accumulation from site-specific and general C sequestration studies. The average annual rate of C storage is highest when mine land is reclaimed to forest, where the potential sequestration is 0.7 to 2.2 Tg yr(-1). The C from soils, litter layer, and biomass from mine lands reclaimed to forest represents 0.3 to 1.0% of the 1990 CO2 emissions from the study region (919 Tg CO2). To achieve the greenhouse gas (GHG) emission reduction goal of 7% below the 1990 level as proposed by the Kyoto Treaty requires CO2 emissions in the study area to be reduced by just over 64 Tg CO2. The potential carbon storage in mine sites reclaimed to forest could account for 4 to 12.5% of these required reductions.