Spatial emission reduction effects of China’s carbon emissions trading:quasi-natural experiments and policy spillovers

Insufficient assessment of emission reduction effects still exists in the carbon emission rights trading system,a major environmental regulation measure in China.Based on the data from the carbon trading pilot covering the years from 2007 to 2017,this study combined the synthetic control method with dynamic spatial Durbin model to comprehensively evaluate the spatial emission reduction effects of carbon trading policies.The results showed that:①The carbon trading policies promoted carbon emission reductions in the pilot regions,among which Tianjin and Hubei responded significantly,and also helped to suppress carbon emissions in the neighboring areas.②Long-term emission reduction effect from carbon emissions trading became gradually significant,while the indirect emission reduction effect was relatively weaker.③In term of reducing carbon emissions,the economic development channel played a key role,but it had a threat to the promotion of carbon emissions in the surrounding areas.Energy consumption was the main obstacle to the growth of carbon emissions.④In the long run,technological progress tended to become the key to the effective implementation of potential emission reduction effects of carbon trading policies.Based on the above findings,we suggest that the construction of a national carbon trading market should be promoted,the balanced development and orderly advancement of regional carbon trading markets should be paid attention to,the coordinated development of green economy as well as knowledge and technology exchange and cooperation among regions should be strengthened to form a low carbon development model among regions.

The Chemical Principle of Green Coal Power

Coal is still a major source of energy, also a major source of SO_2, NOx and CO_2 emission though. Removal of SO_2 and NOx doubled the cost of power generation, and capture of CO_2 is equivalent to double the market price of power coal. The GCP （green coal power） is the power generated in coal-combustion with zero emission. The author indicates that it is possible to make coal-fired power plants emission free based on thermodynamic analysis and purposely designed experiments using SFG （simulated flue gases）. It is concluded in the study that all SO_2 and NOx in the post-combustion flue gas are reduced to inoffensive substances at temperature lower than 750 ℃ when contacting carbon and elemental sulfur is separated in succeeded cooling of flue gas at temperatures 200-400 ℃, and the ultrafine dusts are trapped in condensed water at temperature blow 100 ℃. Based on chemical engineering expertise the author is sure that the cost for removing acid gases is much lower than any clean coal technologies known to today. Instead of capture, the remained CO_2 is converted to CO in the second time contact with carbon at 900-950 ℃. CO is the raw material of chemical synthesis and, thus, CO_2 is stored in chemical products such as methanol, fertilizer, plastics, etc. The simple and low-cost processing allows GCP utilized in practice easily.

Carbon Dioxide Control-Technology for the Future

The world is experiencing global climate change, and most scientists attribute it to the accumulation in the atmosphere of carbon dioxide, methane, nitrous oxide, and chlorofluorocarbons. Because of its enormous emission rate, carbon dioxide （CO2） is the main culprit. Almost all the anthropogenic CO2 emissions come from the burning of fossil fuels for electricity, heat, and transportation. Emissions of COg can be reduced by conservation, increased use of renewable energy sources, and increased efficiencies in both the production of electrical power and the transportation sector. Capture of CO2 can be accomplished with wet scrubbing, dry sorption, or biogenic fixation. After CO2 is captured, it must be transported either as a liquid or a supercritical fluid, which realistically can only be accomplished by pipeline or ship. Final disposal of CO2 will either be to underground reservoirs or to the ocean; at present, the underground option seems to be the only viable one. Various strategies and technologies involved with reduction of CO2 emissions and carbon capture and sequestration （CCS） are briefly reviewed in this paper.

Development of Carbon Dioxide Capture Technologies in Coal-Fired Power Plants

With a particular reference to China Huaneng Group's practices in CO_2 capture, this article presents a brief ing on the current development of CO_2 capture technologies in coal-fired power plants both in China and abroad. Sooner or later, the integration of CO_2 capture and storage (CCS) facility with coal-fired power plant will be inevitably put on the agenda of developers.

Developmental Status Quo and Trends of Low-carbon Agriculture

In order to reduce carbon emission in agricultural production,this paper has discussed the developmental trends of low-carbon agriculture in terms of developing precision agriculture,improving the efficiency of fertilizer utilization,scientific use of pesticides,water-saving irrigation,ecological control of pests and diseases,as well as energy conservation and emission reduction by agricultural machinery and other agricultural practices.

Carbon reduction potential and cost evaluation of different mitigation approaches in China’s coal to olefin Industry

Coal-based olefin(CTO)industry as a complement of traditional petrochemical industry plays vital role in China’s national economic development.However,high CO2 emission in CTO industry is one of the fatal problems to hinder its development.In this work,the carbon emission and mitigation potentials by different reduction pathways are evaluated.The economic cost is analyzed and compared as well.According to the industry development plan,the carbon emissions from China’s CTO industry will attain 189.43 million ton C02(MtC02)and 314.11 MtC02 in 2020 and 2030,respectively.With the advanced technology level,the maximal carbon mitigation potential could be attained to 15.3%and 21.9%in 2020 and 2030.If the other optional mitigation ways are combined together,the carbon emission could further reduce to some extent.In general,the order of mitigation potential is followed as:feedstock alteration by natural gas>C02 hydrogenation with renewable electricity applied>CCS technology.The mitigation cost analysis indicates that on the basis of 2015 situation,the economic penalty for feedstock alteration is the lowest,ranged between 186 and 451 CNY/tCO2,and the cost from CCS technology is ranged between 404 and 562 CNY/tC02,which is acceptable if the C02 enhanced oil recovery and carbon tax are considered.However,for the C02 hydrogenation technology,the cost is extremely high and there is almost no application possibility at present.

保供降碳目标下能源转型模式及转型时点分析

应对气候变化目标要求全球能源系统进行广泛而深刻的转型。由于资源禀赋、能源战略、技术水平等差异,各国能源转型进程呈现出明显的异质性特征。通过对主要国家能源转型特征与减煤路径的分析,归纳了4种典型模式:能效提高模式、增气减煤模式、煤炭洁净利用模式、新能源替代模式,不同模式在不同时间点上与经济社会发展交互影响形成了国际能源转型的内在驱动机制。采用面板数据模型识别了影响能源转型模式的重要因素,并利用历史趋势分析方法对我国化石能源消费“拐点”与减煤时间节点进行研究。研究表明,当人均GDP达到25500美元时,发达国家即出现化石能源减少拐点。国家创新指数和城镇化与煤炭消费占比呈负相关,第二产业增加值占比与煤炭消费占比呈正相关。我国预计减煤时间范围在2028-2035年,化石能源消费减少时点在2040年左右。考虑到我国以煤炭为主的能源资源禀赋,我国能源转型目标的实现须依赖于煤炭洁净利用为主的转型路径,大力发展低碳化现代煤基能源体系,改变传统煤炭利用理念与方式,为未来多能耦合的新型能源体系提供重要支撑。

环境补贴能提升企业碳绩效吗--基于A股上市公司实证分析

环境补贴既是国家实现“双碳”目标的宏观调控手段,也是减轻企业环保负担、引导企业节能减排的推动力。选取2014~2019年接受环境补贴的1094家A股上市公司3735个观测值作为研究样本,采用双向固定效应模型,实证探究环境补贴对企业碳绩效的影响。研究表明,环境补贴与企业碳绩效显著正相关且具有滞后性特征,异质性检验发现,成立时间长的企业、国有企业、东部地区与中低污染企业环境补贴作用效果显著;进一步研究发现,环境补贴中的节能减排补贴与企业碳绩效显著正相关,环境治理补贴对企业碳绩效起负向作用。据此,提出环境补贴应以降碳为重点、减污降碳协同增效为目的等建议。

中国煤炭价格与碳排放权交易价格的传导路径研究

碳市场作为新兴市场易受能源价格因素干扰,在“双碳”目标下研究煤炭价格与碳排放权交易价格(以下简称为碳价)的传导路径,有利于碳市场的健康运行并助力其发挥减排作用。在梳理煤炭价格与碳价传导机理的基础上,利用DCC-GARCH模型揭示煤炭指数与碳价的动态关系,并运用VAR模型实证检验煤炭价格与碳价的传导路径及能源消费结构、能源效率与动态相关系数的因果关系。实证结果表明:煤炭价格与碳价存在显著动态相关性,并呈现复杂性和多变性;碳市场尚未充分发挥其创新激励效应,相较于能源利用效率,煤炭价格与碳价通过能源消费结构路径实现的传导更加显著;能源消费结构调整是动态相关系数变化的格兰杰原因,而能源利用效率改变则不是。

煤炭地下气化碳减排技术研究进展与未来探索

煤炭地下气化(UCG)与碳减排的相互融合,有望成为当前至碳中和到来之前过渡阶段的优秀绿色能源技术,甚至在未来更长的碳中和历史时期发挥重要作用。回顾研究历史与现状,UCG减排系统策略基本形成,可归纳为5种具体途径。其中,地下原位定向调控可减少CO_(2)释放产出并促进UCG提质增产,相关策略和途径可归纳为“碳调减(CRR)”。UCG-CO_(2)地下空间超临界气态封存研究成果相对较多,主要集中在封存介质、封存空间、封存能力等方面,少数研究讨论了封存机制。UCG-CO_(2)地下空间矿化封存不受地质体稳定性和封闭性苛刻条件的约束,潜在着固碳和转化产气的双重效果,但研究成果尚不多见。UCG-CO_(2)回注利用与封存的前期探索集中在煤层气增产和UCG合成气生产改善2个方面,近年来开创了UCG制氢尾气CO_(2)减排利用系列性探索。CRR作为一种主动减排策略,通过调节气化剂及其注入方式来定向调减UCG合成气中CO_(2)浓度,理论成果较多并且经过现场初步验证,有望成为集清洁能源生产与碳减排为一体的洁净煤实用技术。评述进展并分析短板,UCG碳减排科学技术研究已取得诸多实质性成果,也面临持续发展的挑战,未来探索似应聚焦在4个方向:一是立足可行,优先发展以UCG-CRR为重点的UCG-CO_(2)地下转化利用技术;二是聚焦短板,着力突破UCG减排-合成气提质协同机理和关键技术瓶颈;三是扎实推进,优先启动实施UCG-CRR先导试验和工程示范,探索步步取得实效;四是保障实现,探索建立由碳中和与碳管理战略、专项科技行动计划、专业人才培养构成的“三位一体”UCG减排政策支撑体系。

双碳背景下燃煤电站掺氨燃烧研究进展与展望

在“双碳”背景下,选择低碳燃料氨对燃煤电站的改造显得尤为重要。该文首先介绍氨的基本物性及其掺烧的优势,随后针对氨煤掺烧技术的新应用,按照燃煤设备的输出功率分类,从微/小型掺氨燃烧器、千瓦级燃煤掺氨燃烧系统、兆瓦级燃煤掺氨燃烧系统,大型燃煤电站掺氨燃烧系统,介绍当前的研究进展。最后,对燃煤电站掺氨燃烧的前景进行分析与展望。燃煤电站掺氨燃烧可大幅降低碳排放,但可能带来NO_x排放问题,通过空气分级、氨预分解、调节氨掺入位置和比例等手段,可以有效控制NO_x排放;目前,仍需解决煤/氨气固两相燃料反应性差异大、NO_(x)浓度高、缺乏大容量高比例燃烧器技术,以及突破“大型给氨+清洁燃氨+灵活运行”的关键技术。

钢铁行业大气污染治理科技发展分析与展望

钢铁行业是我国工业领域重要的大气污染排放源之一,钢铁行业的大气污染治理是降低重点行业污染排放、打好污染防治攻坚战的重中之重。近年来,我国在钢铁行业大气污染治理方面取得了显著成果。总结了我国“十一五”以来钢铁行业污染防治科技工作的部署,并梳理分析了钢铁行业大气污染治理技术发展的阶段。基于末端治理、源头减排和过程控制、全过程耦合控制三个方面技术发展现状,剖析了当前我国钢铁行业在多污染物协同深度减排和实现超低排放面临的形势和问题。最后,面向“十四五”时期,聚焦碳达峰碳中和目标,提出了相关建议,旨在深化大气污染防治科技工作,为建设“美丽中国”和实现“双碳”目标提供关键科技支撑。在未来的发展中,我们有理由相信,在全社会的共同努力下,钢铁行业将迎来更加清洁、高效和可持续的发展。

煤电行业建设项目碳排放环境影响评价技术方法研究:以黄河流域为例

煤电行业是黄河流域内二氧化碳和大气污染物排放的主要来源,将煤电行业碳排放影响评价纳入环境影响评价体系,能够有效助推黄河流域实现减污降碳协同增效.本文以煤电行业碳排放主要影响因素为基础,设计了能够涵盖碳排放全过程的评价指标体系,并结合先进技术、标准规范要求等设定差异化评价基准,构建以约束评价为主、兼顾指导性评价的评价方法,并采用评价方法中的核心评价指标碳排放绩效,对黄河流域现役煤电机组和“十四五”期间新增煤电机组进行碳减排潜力分析.结果表明,通过优化项目设计可实现流域内现役煤电机组碳排放量下降12.7%,“十四五”期间新建煤电机组碳排放增量下降27.1%,其中新增煤电机组装机占比较高的内蒙古自治区、陕西省可实现新增煤电机组碳排放分别下降30.7%和23.0%.研究显示,黄河流域内碳减排潜力大,建议针对黄河流域内碳排放绩效水平较差的特点,从燃煤小机组淘汰、低碳清洁燃料替代等方式推动煤电行业综合治理,建立协同技术相关指标数据管理台账,出台火电行业碳排放影响评价指南,为煤电行业新增建设项目减污降碳协同增效提供有力有效的政策工具.

能源强国目标下煤炭安全保供及高效降碳效力研究

煤炭安全保供及高效降碳效力研究可为能源强国目标下煤炭领域发展规划提供有力的决策支撑。本文从安全保供和高效降碳两个角度入手,研究了煤炭在能源强国目标下继续保持主体能源地位的潜力、能力和实力,着重通过构建煤炭安全保供的系统动力学模型预测了煤炭安全保供的效力,分析了2060年前煤炭领域的降碳效力。研究结果表明:我国煤炭的可采储量和资源分布是安全保供的基本保障,结合近20年煤炭供应和消费关系可知,我国煤炭资源具备稳定、安全、坚实的保供能力;未来煤炭的安全保供效力在波动中逐渐趋向于动态的柔性平衡;传统煤炭能源向煤基能源过渡效力是构建能源强国目标下新型能源体系的重要环节。我国煤炭领域在清洁转化与利用中体现出显著的降碳潜力,未来随着煤炭地下气化和富油煤开发利用等技术的发展应用将展现出较强的降碳效力,至2060年总体的降碳效力约为1×10^(9)t。

陆上石油天然气开采过程中减污降碳协同管控

石油天然气行业是挥发性有机物(VOCs)排放的重要源头,也是甲烷(CH_(4))的最大工业释放源。在石油天然气开采中对VOCs与CH_(4)进行协同管控,实现减污降碳,对我国大气环境治理和“双碳”目标实现具有重要意义。石油天然气开采过程中大部分VOCs和CH_(4)释放源具有同根同源性,其中工艺有组织排放和火炬排放分别为最大的VOCs释放源和CH_(4)释放源;在加入新型网络化监测的协同管控路径基础上,选择适宜的管控措施,可提高污染物协同管控的效率;治理成本效益核算中多污染物成本效益法具有更高的经济效益,吸收法和吸附法是技术成熟度和经济性较高的VOCs治理技术,而减少压缩机和发动机启动次数是最经济的CH_(4)减排措施。

利用脱碳气化渣矿化封存CO_(2)制备碳酸钙的影响研究

本实验研究了浸出剂种类、浓度、反应时间、温度和液固比等对脱碳气化渣中钙浸出率的影响,并讨论了CO_(2)流量、温度、碳酸化时间对碳酸化效率和生成的沉淀碳酸钙(PCC)晶型结构的影响规律。结果表明,在2 mol/L盐酸、液固比为20 mL/g、反应温度为50℃、反应时间为90 min的浸出条件下,钙浸出率最高,为98.79%。在碳酸化阶段,CO_(2)流量主要影响碳酸化效率,通过优化碳酸化反应条件,CO_(2)流量300 mL/min,反应温度60℃,反应120 min时,最高碳酸化效率可达99.59%。而反应温度和时间则会对碳酸钙晶型和形貌产生显著影响,降低反应温度和缩短反应时间更有利于球霰石型碳酸钙的生成。

“双碳”战略下煤矿减碳实施路径研究

随着“双碳”战略的推进,煤炭生产企业提出“零碳矿山”等建设目标,着力降低煤炭开采过程的碳排放。在煤矿碳排放来源和结构组成分析的基础上,提出减碳、零碳和负碳多组合技术实施路径,以西部某2 000万t/a新建在产矿井为例,定量分析了碳排放量和减碳实施路径及减碳贡献。结果表明,仅靠煤矿能源系统低碳化改造和矿区碳汇减排贡献量有限,还需发展风光新能源绿电、优化开采工艺减少CH_(4)和CO_(2)逃逸排放、开展CO_(2)矿化等技术来实现大幅减碳,最终实现煤矿“零碳”开采生产。

从排污费到环保税:绿色税制改革视阈下的减污降碳协同治理研究

如何将现有的污染防治工作与当前降碳任务有效衔接,是推动绿色税制改革向协同治理方向发展的关键。本文基于地级市样本数据,运用双重差分模型,探讨绿色税制改革视阈下环保“费改税”对减污与降碳的协同效应以及作用机制,着重考察“排污费”和“环保税”对协同减排的差异影响。研究发现:(1)《环境保护税法》的实施能够促进大气污染物与温室气体协同减排,具有减污和降碳的双重效应;并且,政策效果因地理区域、资源类型、环境司法情况的不同而存在显著的异质性。(2)环保费改税所发挥的协同减排效应主要是通过信号导向下环境关注的提高、能源结构转型与能源效率提升、资源配置效应下污染企业的退出与清洁企业的进入等三条渠道实现。(3)进一步比较分析排污费和环保税,发现排污费政策并不具备降碳及协同效应;环保费改税后,央地资金分成模式的改变能在一定程度上缓解地方财政压力,促进其发挥减污和降碳协同效应;税率提升幅度亦会影响协同治理效果。本文为进一步完善绿色税制,构建污染防治与“双碳”目标融合统筹的战略体系提供参考建议。

燃煤发电机组碳排放计算与碳减排技术分析

针对燃煤发电机组的特点,根据CO_(2)生成机理,构建了适用于燃煤机组的碳排放强度计算模型。基于46台机组试验数据,利用该模型研究了碳排放强度随机组等级、煤质以及机组负荷等因素变化关系,并给出了降低供电CO_(2)排放的措施。结果表明:机组的发电碳排放强度主要受机组发电煤耗率、燃煤的收到基低位发热量和燃煤收到基碳元素含量影响。通过数据拟合了碳排放强度与发电煤耗率间估算公式,烟煤的单位标准煤CO_(2)生成系数为2.79 t/t。安徽省2021年平均供电碳排放强度下降到658 g/(kW·h),通过提高新能源装机和电量占比、提升燃煤机组效率,燃煤耦合生物质发电,碳捕集、封存与利用技术及低碳调度等措施,可显著降低区域电力碳排放强度。

煤炭开采企业绿色全要素能源效率研究

煤炭开采行业是高碳能源的生产行业,提升煤炭开采企业的绿色全要素能源效率对促进我国“双碳”目标的实现具有重要作用。基于影子价格模型,对企业的二氧化碳边际减排成本进行测算,进而构建DEA-Malmquist指数模型计算煤炭开采企业绿色全要素能源效率。实证结果表明:样本企业绿色全要素能源效率水平参差不齐,但均呈现不同程度的上升趋势;相对于综合技术效率,技术进步对企业绿色全要素能源效率水平上升做出了更多贡献。基于上述结果,从企业内部、外部2个视角对影响企业绿色全要素能源效率的因素进行分析,通过专利分析企业自主研发能力及技术选择、分析外部政策环境,提出完善碳交易市场形成有效监管、适当扩张企业规模提高规模效率、加强自主研发走内涵式发展道路等对策建议。