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1.
This article provides further detail on expected global GHG emission levels in 2020, based on the Emissions Gap Report (United Nations Environment Programme, December 2010), assuming the emission reduction proposals in the Copenhagen Accord and Cancun Agreements are met. Large differences are found in the results of individual groups owing to uncertainties in current and projected emission estimates and in the interpretation of the reduction proposals. Regardless of these uncertainties, the pledges for 2020 are expected to deliver emission levels above those that are consistent with a 2°C limit. This emissions gap could be narrowed through implementing the more stringent conditional pledges, minimizing the use of ‘lenient’ credits from forests and surplus emission units, avoiding double-counting of offsets and implementing measures beyond current pledges. Conversely, emission reduction gains from countries moving from their low to high ambition pledges could be more than offset by the use of ‘lenient’ land use, land-use change and forestry (LULUCF) credits and surplus emissions units, if these were used to the maximum. Laying the groundwork for faster emission reduction rates after 2020 appears to be crucial in any case.  相似文献   

2.
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   

3.
Countries with emission levels below their emission allowances have surplus Assigned Amount Units (AAUs) or other emission credits. Under the Kyoto Protocol, these surplus credits may effectively be carried from the first to a following commitment period. In the climate negotiations, various rules for carry-over and sale of surplus allowances have been put forward. This paper analyses the effect of these options on the reduction pledges for 2020, taking into account the estimated credits from the Clean Development Mechanism, Joint Implementation projects, and land-use activities for the first commitment period. For current Kyoto Protocol rules of unlimited carry-over of surplus allowances and limited carry-over of other credits, the environmental effectiveness of reduction pledges could be seriously undermined. For the group of countries that showed a willingness to participate in a second commitment period, it could imply that instead of an aggregated 2020 target resulting from the pledges of 18 to 28?% below 1990 levels by 2020, their emissions could return to business-us-usual emission projections. For the EU, a 30?% target by 2020 could imply higher emissions compared to a 20?% target, if surplus allowances would be used for achieving the 30?% but not for the 20?% target. Restricting the use of Kyoto surplus units to domestic use only, would limit the problem, but still seriously undermine the effectiveness of 2020 reduction targets.  相似文献   

4.
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   

5.
 由土地利用、土地利用变化和林业(LULUCF)活动产生的生态系统的固碳作用,是降低大气中温室气体浓度增加速度的重要途径之一。1997-2001年,经历了长达4 a的艰苦谈判,最终达成了第一承诺期附件一国家利用LULUCF的规则。2008年开始,国际社会开始磋商第二承诺期附件一国家如何利用LULUCF活动的规则。主要缔约方就第二承诺期LULUCF规则提出了各自的观点,发达国家的观点主要包括提高开展碳汇活动的积极性、降低LULUCF规则的复杂性和减少成本、增加《京都议定书》3.4条款下的合格活动等,其目的是在第二承诺期能够利用更多的碳汇完成减排义务;发展中国家主要提出要系统地考虑土地利用造成的温室气体排放和CO2的吸收。最后,针对附件一缔约方在第二承诺期利用LULUCF活动规则,提出了我国应采取的对策建议。  相似文献   

6.
由土地利用、土地利用变化和林业(LULUCF)活动产生的生态系统的固碳作用,是降低大气中温室气体浓度增加速度的重要途径之一。1997-2001年,经历了长达4 a的艰苦谈判,最终达成了第一承诺期附件一国家利用LULUCF的规则。2008年开始,国际社会开始磋商第二承诺期附件一国家如何利用LULUCF活动的规则。主要缔约方就第二承诺期LULUCF规则提出了各自的观点,发达国家的观点主要包括提高开展碳汇活动的积极性、降低LULUCF规则的复杂性和减少成本、增加《京都议定书》3.4条款下的合格活动等,其目的是在第二承诺期能够利用更多的碳汇完成减排义务;发展中国家主要提出要系统地考虑土地利用造成的温室气体排放和CO2的吸收。最后,针对附件一缔约方在第二承诺期利用LULUCF活动规则,提出了我国应采取的对策建议。  相似文献   

7.
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   

8.
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   

9.
后京都时期LULUCF潜在核算规则分析   总被引:1,自引:0,他引:1       下载免费PDF全文
《京都议定书》附件一缔约方国家通过土地利用、土地利用变化和林业(LULUCF)活动产生的碳汇减轻自身减排压力,为国内工业能源部门碳排放提供空间。但LULUCF包括的核算活动类型和具体方法一直是各方争论的焦点,其中木质林产品、不可抗力等自然干扰、参考水平阈值的设置以及总-净与净-净核算方式的选择这几方面核算漏洞很多,矛盾尤为突出。为防止发达国家过分依赖LULUCF产生的碳汇减轻减排压力,搜集了欧盟27国、加拿大、日本、俄罗斯等发达国家提交的LULUCF数据,分析了核算漏洞对LULUCF核算结果可能产生的影响。结果表明:木质林产品活动的核算方法不确定性较多;剔除自然干扰等不可抗力后,LULUCF活动碳汇至少增加30%;参考水平阈值适于设置在较高碳汇水平;净-净核算方式更适用于后京都时代LULUCF核算规则。  相似文献   

10.
In this paper we argue that the financial provisions of the Copenhagen Accord, if used primarily to mitigate greenhouse gas (GHGs) emissions, could compensate the lack of more energetic action on the domestic mitigation side. In order to maximize the mitigation potential, the Copenhagen Green Climate Fund (CGCF) should be transformed into the International Bank for Emissions Allowance Acquisition (IBEAA) envisaged by Bradford (2008). We estimate that 50 percent of the CGCF in 2020 (50 US billions) could finance from 2.1 to 3.3?Gt CO2-eq emission reductions, depending on the domestic mitigation effort of Annex I and Non-Annex I countries. We construct a matrix that shows the level of GHGs emissions in 2020 under all possible combinations of abatement pledges and international mitigation financing, thus highlighting a rich set of options to reach the same level of GHGs emissions in 2020.  相似文献   

11.
We present and apply a simple bottom–up model for estimating non-energy use of fossil fuels and resulting CO2 (carbon dioxide) emissions. We apply this model for the year 2000: (1) to the world as a whole, (2) to the aggregate of Annex I countries and non-Annex I countries, and (3) to the ten non-Annex I countries with the highest consumption of fossil fuels for non-energy purposes. We find that worldwide non-energy use is equivalent to 1,670 ± 120 Mt (megatonnes) CO2 and leads to 700 ± 90 Mt CO2 emissions. Around 75% of non-energy use emissions is related to industrial processes. The remainder is attributed to the emission source categories of solvent and other product use, agriculture, and waste. Annex I countries account for 51% (360 ± 50 Mt CO2) and non-Annex I countries for 49% (340 ± 70 Mt CO2) of worldwide non-energy use emissions. Among non-Annex I countries, China is by far the largest emitter of non-energy use emissions (122 ± 18 Mt CO2). Our research deepens the understanding of non-energy use and related CO2 emissions in countries for which detailed emission inventories do not yet exist. Despite existing model uncertainties, we recommend NEAT-SIMP to inventory experts for preparing correct and complete non-energy use emission estimates for any country in the world.  相似文献   

12.
During the negotiations on the Kyoto Protocol, Brazil proposed a methodology to link the relative contribution of Annex I Parties to emission reductions with the relative contributions of Parties to the global-mean temperature increase. The proposal was not adopted during the negotiations but referred to the Subsidiary Body for Scientific and Technological Advice for consideration of its methodological aspects. In this context we analyze the impact of model uncertainties and methodological choices on the regionally attributed global-mean temperature increase. A climate assessment model has been developed to calculate changes in greenhouse gas concentrations, global-mean temperature and sea-level rise attributable to individual regions. The analysis shows the impact of the different choices in methodological aspects to be as important as the impact of model uncertainties on a region's contribution to present and future global temperature increases. Choices may be the inclusion of the anthropogenic non-CO2 greenhouse gas emissions and/or theCO2 emissions associated with land-use changes. When responsibility to global temperature change is attributed to all emitting Parties, the impacts of modeling uncertainties and methodological choices on contributions of individual Parties are considerable. However, if relative contributions are calculated only within the group of Annex I countries, the results are less sensitive to the uncertainty aspects considered here.  相似文献   

13.
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   

14.
The outcome from the December 2012 climate negotiations in Doha has clarified the rules regarding surplus units for the Kyoto Protocol. We summarize these new rules and estimate the resulting effective emissions during the second commitment period using our unit trade model. Other options to deal with surplus emission allowances are employed as benchmarks to assess the Doha outcome. The effective emissions for developed countries as a group under the Doha outcome could be 10–11 % below 1990 levels or 4–5 % points below business-as-usual levels for the second commitment period if we assume that non-Kyoto Protocol countries domestically achieve their targets. However, if mechanisms exist where non-Kyoto Protocol countries can trade units, their emissions could increase and effective emissions for developed countries could be 7–8 % below 1990 levels. In this low-ambition situation we find the main impact of the Doha surplus rules to be the introduction of the historical cap on emissions allowances. Without the effect of the cap, the Doha outcome allows the Parties to the second commitment period to emit at business-as-usual levels until 2020, while still leaving surplus units at the end of the second commitment period.  相似文献   

15.
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   

16.
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   

17.
《Climate Policy》2013,13(4):379-385
Abstract

The Bonn agreement reached in July at the sixth conference of the parties (COP) to the FCCC states “that for the first commitment period, the total of additions to and subtractions from the assigned amount of a party resulting from eligible LULUCF activities under Article 12 (i.e. CDM), shall not exceed 1% of base-year emissions of that party, times five”. The most probable size of this LULUCF-CDM market is analyzed in light of each Annex I party's actual and projected emissions and policies. Results show that the market size would be only about 110 Mt CO2 eq. for 2000–2012, representing a maximum global market value of about US$ 876 million.  相似文献   

18.
The contribution of deforestation in Russia to the anthropogenic emission of carbon dioxide (CO2) in 1990–2013 is estimated using the methods of computational monitoring. It is found that since 1990 the area of deforestation and forest conversion to other land-use categories is equal to 628.4 x 103 ha. The respective CO2 emissions from deforestation in Russia for the whole analyzed period are estimated at 142200 kt CO2 with the average annual value of 5900 + 2270 kt CO2/year. The largest contribution to the total losses is made by the changes in soil carbon stock (41.6%) and biomass carbon losses (28.8%). CO2 emissions from deforestation make an insignificant contribution to the total anthropogenic CO2 emission in the country (0.2%). Among the CO2 sources in the land use, land-use change, and forestry sector (LULUCF), the emission from deforestation is the lowest with the average for 1990–2013 contribution of about 0.6%.  相似文献   

19.
《Climate Policy》2002,2(4):379-385
The Bonn agreement reached in July at the sixth conference of the parties (COP) to the FCCC states “that for the first commitment period, the total of additions to and subtractions from the assigned amount of a party resulting from eligible LULUCF activities under Article 12 (i.e. CDM), shall not exceed 1% of base-year emissions of that party, times five”. The most probable size of this LULUCF-CDM market is analyzed in light of each Annex I party’s actual and projected emissions and policies. Results show that the market size would be only about 110 Mt CO2 eq. for 2000–2012, representing a maximum global market value of about US$ 876 million.  相似文献   

20.
In order to properly assess the climate impact of temporary carbon sequestration and storage projects through land-use, land-use change and forestry (LULUCF), it is important to consider their temporal aspect. Dynamic life cycle assessment (dynamic LCA) was developed to account for time while assessing the potential impact of life cycle greenhouse gases (GHG) emissions. In this paper, the dynamic LCA approach is applied to a temporary carbon sequestration project through afforestation, and the results are compared with those of the two principal ton-year approaches: the Moura-Costa and the Lashof methods. The dynamic LCA covers different scenarios, which are distinguished by the assumptions regarding what happens at the end of the sequestration period. In order to ascertain the degree of compensation of an emission through a LULUCF project, the ratio of the cumulative impact of the project to the cumulative impact of a baseline GHG emission is calculated over time. This ratio tends to 1 when assuming that, after the end of the sequestration project period, the forest is maintained indefinitely. Conversely, the ratio tends to much lower values in scenarios where part of the carbon is released back to the atmosphere due to e.g. fire or forest exploitation. The comparison of dynamic LCA with the ton-year approaches shows that it is a more flexible approach as it allows the consideration of every life cycle stage of the project and it gives decision makers the opportunity to test the sensitivity of the results to the choice of different time horizons.  相似文献   

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