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1.
对<联合国气候变化框架公约>秘书处最新公布的温室气体排放数据进行统计分析,结果显示:相对于基准年(1990年),附件-国家温室气体排放总量整体呈下降趋势.其中,经济转型期国家温室气体排放总量总体上呈逐年下降趋势,非经济转型期国家的温室气体排放总量有逐年增长的趋势.美国和加拿大能源部门的温室气体排放量增长最为显著,相对于1990年,2005年其增幅分别为19.2%和28.6%;英国和德国能源部门温室气体减排量最为显著,其减幅分别为7.8%和17.4%.在2005年,有超过一半的附件-国家的实际排放量低于其目标排放量,履约进展状况良好. 相似文献
2.
附件一国家温室气体排放趋势及其履约进展 总被引:2,自引:0,他引:2
对《联合国气候变化框架公约》秘书处最新公布的温室气体排放数据进行统计分析,结果显示:相对于基准年(1990年),附件一国家温室气体排放总量整体呈下降趋势。其中,经济转型期国家温室气体排放总量总体上呈逐年下降趋势,非经济转型期国家的温室气体排放总量有逐年增长的趋势。美国和加拿大能源部门的温室气体排放量增长最为显著,相对于1990年,2005年其增幅分别为19.2%和28.6%;英国和德国能源部门温室气体减排量最为显著,其减幅分别为7.8%和17.4%。在2005年,有超过一半的附件一国家的实际排放量低于其目标排放量,履约进展状况良好。 相似文献
3.
采用IPCC指南推荐的碳排放计算方法,将省级温室气体排放源分为能源活动、工业生产、农业、林业、废弃物等5个单元,全面测算了2005—2013年陕西省温室气体排放清单。结果表明:2005—2013年,陕西省温室气体排放总量和人均碳排放量逐年增长且有加速趋势,而温室气体吸收总量却增长缓慢,净温室气体排放量增长趋势显著,单位GDP碳排放量呈波动下降趋势;能源部门的温室气体排放量占总排放比例最大,为78.42%~83.36%;工业过程、农业、废弃物处理排放所占比例分别为9.57%~14.78%、3.11%~9.02%、1.25%~1.98%;林业部门表现为碳汇,约9%的CO2排放被森林吸收。 相似文献
4.
2003—2009年中国污水处理部门温室气体排放研究 总被引:5,自引:0,他引:5
基于《中国环境统计年报》等的统计数据,采用IPCC提供的方法估算了2003—2009年我国源自污水处理部门的温室气体排放量,并对污水处理部门人均温室气体排放量进行分析。结果表明,2003—2009年污水处理部门温室气体排放呈增加趋势,源自生活污水的N2O排放是主要排放源,生活污水CH4排放增速最快;工业行业中造纸业废水的CH4排放是主要排放源;人均温室气体排放量呈现递增趋势。 相似文献
5.
污水处理厂运行过程中大量释放甲烷(CH4)和氧化亚氮(N2O),是重要的人为温室气体排放源。基于2005—2015年统计资料和IPCC核算方法,估算了2005—2015年中国生活污水处理厂CH4和N2O排放,分析了其排放特征和影响因素;依据碳中和愿景设定3种减排情景(低减排、中减排和高减排),并预估了2020—2050年排放趋势和时空变化。结果表明:2005—2015年间污水处理厂温室气体排放量呈稳定增长趋势,CH4从1135.37万t CO2e上升至1501.45万t CO2e,N2O从2651.08万t CO2e上升为2787.05万t CO2e,年均增速分别为2.8%和0.5%。3种减排情景下,2020—2050年CH4和N2O排放量时间上呈先增后减趋势,低减排情景下CH4和N2O排放量分别于2036年和2025年达到峰值,分别为2431万和2819万t CO2e;中减排情景和高减排情景下CH4峰值点分别出现在2027和2025年,而N2O排放峰值均出现在2025年。2050年中减排和高减排情景下CH4排放量相较于低减排情景减排率约为47%和94%;2050年低减排、中减排和高减排情景下N2O排放量相较于2015年分别减排了12%、53%和95%。CH4和N2O排放量在空间上差异显著,华东地区排放量高,西北地区排放量低,东南区域所在省份排放量整体高于西北区域省份。影响因素中的经济发展程度与温室气体排放量密切相关。 相似文献
6.
基于各国提交的165份国家自主贡献文件,以其中提出的减排目标为基准,尽可能充分地考虑了减排目标的范围不确定性、不同经济情景带来的碳强度减排目标不确定性、减排气体种类边界差异、碳排放达峰约束等因素,并通过蒙特卡洛模拟的方法对全球、各区域和主要经济体的温室气体排放总量、不确定度及其来源进行了定量分析。结果表明,到2030年全球温室气体排放总量将达到62.69 Gt CO2当量,其90%信度的置信区间为53.17~74.26 Gt CO2当量;由于未来经济总量预期不确定对排放量的影响最显著,因此,不同地区之间不确定性来源差异较大。同时,基于到2050年排放总量比2010年下降40%~70%的2℃目标排放情景,2030—2050年全球温室气体排放年均需要下降5.0% %。为了尽可能减小全球温室气体排放预期目标的不确定性和继续实现2℃目标,各国在进行自主贡献文件更新时进一步提出统计边界更为明确和统一且更有雄心的减排目标将是第一次全球盘点继续解决的重点问题。 相似文献
7.
下面介绍主要工业国对限制温室气体排放达成的最新协议和计划."环境部长们对到2000年稳定CO _2的排放量达成一致协议"(Intl.Environ.Rptr.7卷,457~458页)欧共体部长们认为整个欧洲(除希腊、葡萄牙、西班牙等经济需急剧增长的国家外)的CO_2排放量应限制在1990年水平上.美国的目标是到2005年达到稳 相似文献
8.
通过对国际能源机构(IEA)最新公布的各国CO2排放量进行分析对比,结果显示,1990-2005年世界按购买力平价计算的CO2排放量整体呈下降趋势,降幅较大,而且在2000年之后基本保持稳定。经济合作与发展组织(OECD)国家按购买力平价计算的CO2排放量也有不同程度的减少,非OECD国家按购买力平价计算的CO2排放量与1990年相比整体上也呈现负增长,但各国情况相差较大。在人均排放量方面OECD国家普遍高于世界平均水平,而大多数非OECD国家则低于世界平均水平。 相似文献
9.
不同温室气体排放情景下中国21世纪地面气温和降水变化的模拟分析 总被引:38,自引:2,他引:36
利用HadCM2模式的模拟结果,比较了温室气体排放综合效果相当于CO2浓度逐年递增1%和0.5%两种不同情景下,中国区域21世纪地面气温和降水量的变化趋势.结果表明,随着温室气体浓度的持续增加,中国地面气温也持续升高.到21世纪末期,地面气温在上述两种排放情景下可分别升高约5℃和3℃.两种排放情景的增温趋势对比表明:即使从1990年开始温室气体等效排放逐年递增率减少一半,增温仍然很明显;直到21世纪中期,才能显示出减少温室气体排放量对减缓增温趋势的效果.降水量的年际变化较大,但随着温室气体浓度的持续增加,降水量总的趋势也是增加的.减排温室气体对降水量变化趋势的影响与地面气温相似.此外,地面气温增量和降水量变化百分率均显示出明显的季节变化,地面气温增量在秋、冬季较大而在春、夏季较小,降水变化百分率在夏、秋季较小而在冬、春季较大. 相似文献
10.
王绍武 《气候变化研究进展》2013,(1):78
2005年2月开始生效的《京都议定书》要求全球主要工业化国家在2008—2012年减排5.2%(相对于1990年温室气体的排放水平)。由于美国未批准《京都议定书》,剩下的37个工业化国家应减排4.2%。根据《自然》杂志中德国的报告员Schiermeier的论文,这37个国家实际合 相似文献
11.
During the negotiations on the Kyoto Protocol, Brazil proposed allocating the greenhouse gas emission reductions of Annex I Parties according to the relative effect of a country’s historical emissions on global temperature increase. This paper analyses the impact of scientific uncertainties and of different options in policy implementation (policy choices) on the contribution of countries’ historical emissions to indicators of historical responsibility for climate change. The influence of policy choices was found to be at least as large as the impact of the scientific uncertainties analysed here. Building on this, the paper then proceeds to explore the implications of applying the Brazilian Proposal as a climate regime for differentiation of future commitments on the global scale combined with an income threshold for participation of the non-Annex I regions. Under stringent climate targets, such a regime leads to high emission reductions for Annex I regions by 2050, in particular for Europe and Japan. The income threshold assumptions strongly affect the Annex I reductions, even more than the impact of another burden-sharing key. A variant of the Brazilian Proposal, allocating emission reductions on the basis of cumulative emissions since 1990, would lead to a more balanced distribution of emission reductions. 相似文献
12.
As part of the Copenhagen Accord, Annex I Parties (industrialised countries) and non-Annex I Parties (developing countries) have submitted reduction proposals (pledges) and mitigation actions to the UNFCCC secretariat. Our calculations show that if the current reduction offers of Annex I and non-Annex I countries are fully implemented, global greenhouse gas emissions could amount to 48.6-49.7 GtCO2eq by 2020. Recent literature suggests that the emission level should be between 42 and 46 GtCO2eq by 2020 to maintain a “medium” chance (50-66%) of meeting the 2 °C target. The emission gap is therefore 2.6-7.7 GtCO2eq. We have identified a combined set of options, which could result in an additional 2.8 GtCO2eq emission reduction. This would lead to an emission level just within the range needed. The options include reducing deforestation and emissions from bunker fuels, excluding emissions allowance increases from land use and forestry rules, and taking into account the national climate plans of China and India. However, there are also important risks that could widen the emissions gap, like lower reductions from countries with only a conditional pledge and the use of Kyoto and/or trading of new surplus emission allowances. 相似文献
13.
《Climate Policy》2013,13(2):944-957
The annual reporting procedures of the United Nations Framework Convention on Climate Change (UNFCCC) have now produced greenhouse gas (GHG) emission inventories from 40 so-called Annex I countries for 18 years. This article analyses a subset of these data: emissions from road transport. The article compares the reported data with the technical guidance on GHG emission inventories provided by the Intergovernmental Panel on Climate Change (IPCC). The analysis suggests that some countries use the IPCC's default emission factors, whereas other countries use country-specific values. In the case of diesel-fuelled road transport, the estimated emissions appear to be generally comparable between all countries for all years. For CO2 emissions from gasoline-fuelled road transport, the picture is less clear. The results suggest that the default emission factor for CO2 from motor gasoline as provided by the IPCC is about 3–5% too low. Countries that seem to apply this default value might therefore underestimate their emissions by the same percentage. The effect of this possible underestimate on trends is, however, very small. Despite the possible problem with the default emission factor, the quantification of the trend in emissions is only slightly influenced by this. 相似文献
14.
Reductions of greenhouse gas emissions in Annex I and non-Annex I countries for meeting concentration stabilisation targets 总被引:2,自引:1,他引:1
The IPCC Fourth Assessment Report, Working Group III, summarises in Box 13.7 the required emission reduction ranges in Annex I and non-Annex I countries as a group, to achieve greenhouse gas concentration stabilisation levels between 450 and 650 ppm CO2-eq. The box summarises the results of the IPCC authors’ analysis of the literature on the regional allocation of the emission reductions. The box states that Annex I countries as a group would need to reduce their emissions to below 1990 levels in 2020 by 25% to 40% for 450 ppm, 10% to 30% for 550 ppm and 0% to 25% for 650 ppm CO2-eq, even if emissions in developing countries deviate substantially from baseline for the low concentration target. In this paper, the IPCC authors of Box 13.7 provide background information and analyse whether new information, obtained after completion of the IPCC report, influences these ranges. The authors concluded that there is no argument for updating the ranges in Box 13.7. The allocation studies, which were published after the writing of the IPCC report, show reductions in line with the reduction ranges in the box. From the studies analysed, this paper specifies the “substantial deviation” or “deviation from baseline” in the box: emissions of non-Annex I countries as a group have to be below the baseline roughly between 15% to 30% for 450 ppm CO2-eq, 0% to 20% for 550 ppm CO2-eq and from 10% above to 10% below the baseline for 650 ppm CO2-eq, in 2020. These ranges apply to the whole group of non-Annex I countries and may differ substantially per country. The most important factor influencing these ranges above, for non-Annex I countries, and in the box, for Annex I countries, is new information on higher baseline emissions (e.g. that of Sheehan, Climatic Change, 2008, this issue). Other factors are the assumed global emission level in 2020 and assumptions on land-use change and forestry emissions. The current, slow pace in climate policy and the steady increase in global emissions, make it almost unfeasible to reach relatively low global emission levels in 2020 needed to meet 450 ppm CO2-eq, as was first assumed feasible by some studies, 5 years ago. 相似文献
15.
张小全 《气候变化研究进展》2011,7(5):369-377
根据主要附件I缔约方2011年向《联合国气候变化框架公约》递交的1990—2009年国家温室气体(GHG)排放清单数据,包括报告的《京都议定书》土地利用、土地利用变化和林业(LULUCF)活动数据,对其LULUCF GHG源/汇趋势、《京都议定书》缔约方LULUCF相关活动在履约中的作用进行系统的对比分析,对缔约方会议确定的森林管理活动汇清除的限额进行评估。分析表明,1990—2009年,附件I缔约方LULUCF总体表现为净GHG汇清除,且总体上呈波浪式增加趋势,20年增加了65.9%,但年际波动较大。1990年LULUCF汇清除相当于GHG排放总量的7.41%, 2009年上升到13.68%。《京都议定书》第一承诺期的最初两年(2008—2009年),各缔约方每年可从合格的LULUCF活动中获得2.38亿t CO2当量的汇清除,相当于这些缔约方基准年源排放的1.91%,可抵消其减限排额的45%。汇清除主要来自森林管理活动,而其他活动的汇清除所占份额很小。LULUCF活动使《京都议定书》的实施效果大打折扣,为一些缔约方过多地使用森林管理活动的汇清除来完成其减限排指标提供了机会,特别是俄罗斯、日本和意大利等国。这为目前正在谈判的第二承诺期LULUCF规则,特别是如何利用森林管理汇清除的规则敲响警钟。 相似文献
16.
Over the last three decades, socio-economic, demographic and technological transitions have been witnessed throughout the world, modifying both sectorial and geographical distributions of greenhouse gas (GHG) emissions. Understanding these trends is central to the design of current and future climate change mitigation policies, requiring up-to-date methodologically robust emission inventories such as the Emissions Database for Global Atmospheric Research (EDGAR), the European Commission’s in-house, independent global emission inventory. EDGAR is a key tool to track the evolution of GHG emissions and contributes to quantifying the global carbon budget, providing independent and systematically calculated emissions for all countries.According to the results of the EDGAR v.5.0 release, total anthropogenic global greenhouse gas emissions (excluding land use, land use change and forestry) were estimated at 49.1 Gt CO2eq in 2015, 50 % higher than in 1990, despite a monotonic decrease in GHG emissions per unit of economic output. Between 1990 and 2015, emissions from developed countries fell by 9%, while emissions from low to medium income countries increased by 130%, predominantly from 2000 onwards. The 27 Member States of the European Union and the United Kingdom led the pathway for emission reductions in industrialised economies whilst, in developing countries, the rise in emissions was driven by higher emissions in China, India, Brazil and nations in the South-East Asian region. This diversity of patterns shows how different patterns for GHG emissions are and the need for identifying regionally tailored emission reduction measures. 相似文献
17.
Methane emissions from livestock enteric fermentation and manure management represent about 40% of total anthropogenic greenhouse
gas emissions from the agriculture sector and are projected to increase substantially in the coming decades, with most of
the growth occurring in non-Annex 1 countries. To mitigate livestock methane, incentive policies based on producer-level emissions
are generally not feasible because of high administrative costs and producer transaction costs. In contrast, incentive policies
based on sectoral emissions are likely administratively feasible, even in developing countries. This study uses an economic
model of global agriculture to estimate the effects of two sectoral mitigation policies: a carbon tax and an emissions trading
scheme based on average national methane emissions per unit of commodity. The analysis shows how the composition and location
of livestock production and emissions change in response to the policies. Results illustrate the importance of global mitigation
efforts: when policies are limited to Annex 1 countries, increased methane emissions in non-Annex 1 countries offset approximately
two-thirds of Annex 1 emissions reductions. While non-Annex 1 countries face substantial disincentives to enacting domestic
carbon taxes, developing countries could benefit from participating in a global sectoral emissions trading scheme. We illustrate
one scheme in which non-Annex 1 countries collectively earn USD 2.4 billion annually from methane emission permit sales when
methane is priced at USD 30/t CO2-eq. 相似文献
18.
Abstract This article presents a set of multi-gas emission pathways for different CO2-equivalent concentration stabilization levels, i.e. 400, 450, 500 and 550 ppm CO2-equivalent, along with an analysis of their global and regional reduction implications and implied probability of achieving the EU climate target of 2°C. For achieving the 2°C target with a probability of more than 60%, greenhouse gas concentrations need to be stabilized at 450 ppm CO2-equivalent or below, if the 90% uncertainty range for climate sensitivity is believed to be 1.5–4.5°C. A stabilization at 450 ppm CO2-equivalent or below (400 ppm) requires global emissions to peak around 2015, followed by substantial overall reductions of as much as 25% (45% for 400 ppm) compared to 1990 levels in 2050. In 2020, Annex I emissions need to be approximately 15% (30%) below 1990 levels, and non-Annex I emissions also need to be reduced by 15–20% compared to their baseline emissions. A further delay in peaking of global emissions by 10 years doubles maximum reduction rates to about 5% per year, and very probably leads to high costs. In order to keep the option open of stabilizing at 400 and 450 ppm CO2-equivalent, the USA and major advanced non-Annex I countries will have to participate in the reductions within the next 10–15 years. 相似文献