氨水捕集模拟烟气中二氧化碳的实验与理论研究

介绍了氨水捕集CO₂的反应原理, 利用鼓泡反应器开展了氨水碳捕集实验研究. 研究了氨水浓度、CO₂浓度、温度等因素对脱除效率的影响. 研究发现, 提高氨水质量分数和pH值均可增大CO₂脱除效率|增大CO₂浓度和入口气体流量后脱除效率呈现下降趋势|最佳脱除温度为45 ℃. 红外光谱分析表明, 氨水吸收后的主要成分是碳酸氢铵. 研究结果对进一步开展氨法捕集CO₂研究有较大的参考价值.     

非胺类CO2吸收剂的研究进展

针对CO₂所带来的全球气候变化问题,本文综述了可用于捕集CO₂的非胺类吸收剂类型,认为氨基酸盐、氨基酸-碳酸钾体系、离子液体、生物型吸收剂、钙基吸收剂分别具有较高的CO₂循环吸收负荷、低毒性、热稳定性好、较优的生物相容性、钙源易获取的优势,可以弥补胺类吸收剂在吸收-解吸CO₂时腐蚀性强、再生能耗高、对环境产生二次污染等方面的不足。氨基酸盐、氨基酸-碳酸钾体系可应用于具有一定规模的CO₂捕集工业中;离子液体可应用于精准、绿色环保去除CO₂工业中;生物型吸收剂可用于规模小、CO₂浓度低的工业中;钙基吸收剂可运用于CO₂浓度高的工业中。上述吸收剂皆具有一定的工业前景。     

CO2化学吸收剂

化学吸收法是燃后CO₂捕集的主要方法之一,本文介绍了化学吸收法脱除CO₂的系统工艺及特点,综述了CO₂吸收剂的研究现状,介绍了典型吸收剂:氨水吸收剂、氨基酸盐吸收剂、碳酸钾吸收剂的研究进展,以及新型吸收剂研究方向:混合胺吸收剂、相变吸收剂、离子液体吸收剂、纳米流体吸收剂,CO₂开关型吸收剂和新型有机胺吸收剂,并分析比较了各种吸收剂的优缺点。分析表明混合胺和相变吸收剂节能潜力较大,较其他四种新型吸收剂更为成熟,因此具有一定的工业化潜力。     

无机盐活化剂-氨基酸盐基溶液捕集温室气体CO2

将无机盐K₃PO₄、K₂HPO₄和KH₂PO₄作为活化剂,分别添加于氨基乙酸盐溶液中,形成CO₂活化吸收剂,采用膜接触器 再生循环装置,评价和比较了氨基乙酸盐和活化吸收剂捕集CO₂的性能,研究了活化剂的浓度、气液流速等因素对总体积传质系数、传质通量和捕集率的影响。结果表明,磷酸盐活化剂在氨基乙酸盐吸收剂中,对CO₂的捕集均产生影响,活化效应存在PO₄^3－＞HPO₄^2－＞H₂PO₄^－的规律;添加少量活化剂的作用比添加较多量的活化作用大;活化吸收剂的捕集率明显大于非活化吸收剂;膜吸收流体力学状态的改变,能够改善膜接触器传质性能,增大传质通量,但增大的程度有限。     

二氧化碳的捕集、存储及转化

2009年哥本哈根全球气候大会之后,如何减排导致全球气候变暖的温室气体之一的CO₂,并能将CO₂转化成有用化工产品成为当前全球研究的热点.本文总结了至今在CO₂捕集、存储和转化方面的进展工作.另外,结合各种CO₂利用技术的原理和特点,总结出这些技术的优势与不足,对CO₂的利用前景进行了展望.     

膜接触器 复合有机胺溶液捕集CO2(英文）

本文提出一种基于氨基酸盐的CO₂复合吸收剂,采用膜接触器 复合溶液耦合技术研究了吸收CO₂的性能,并与单一氨基酸盐溶液吸收性能进行了比较,讨论了气液流速等因素对气液出口CO₂浓度、捕集效率和总传质系数的影响,开发了一个阻力层模型预测膜接触器的总传质系数。结果表明：复合溶液的性能明显好于单一氨基酸盐溶液;与单一溶液比较,使用复合溶液,气相出口CO₂浓度较低,液相出口CO₂浓度较高,捕集效率也较高;复合溶液的总传质系数明显高于单一溶液。可以证实,在膜吸收过程中氨基酸盐基复合溶液是一高效的CO₂吸收剂。模型的预测值符合实验值。     

Li4SiO4对CO2捕集性能的实验研究

以Li₂CO₃和SiO₂为原料,通过高温固相合成法合成了CO₂捕集剂Li₄SiO₄,并用X射线粉末衍射仪(XRD)、扫描电子显微镜(SEM)对所合成的材料在CO₂捕集前后的晶相变化以及微观结构进行了表征。通过热重分析仪(TGA)研究了Li₄SiO₄材料吸附CO₂的性能,并在小型热态实验台架上进行了CO₂热态捕集实验。实验结果表明,Li₄SiO₄对CO₂的捕集性能受Li₄SiO₄合成温度、CO₂的吸附温度以及气体中CO₂含量的影响,在700 ℃下制得的Li₄SiO₄具有最佳的CO₂吸附特性,最大吸附增量可达34%。Li₄SiO₄的吸附能力随着CO₂含量和吸附时间的增加而增加,当CO₂浓度分别为75%、67%、60%时,700 ℃ Li₄SiO₄对CO₂最大吸附量分别可达6.68 mmol/g、3.37 mmol/g、2.02 mmol/g (理论量8.33 mmol/g)。     

湿气源吸附碳捕集: CO2/H2O共吸附机制及应用

大型湿气源排放中普遍存在的水汽是制约吸附碳捕集规模化发展的重要挑战之一。H₂O的极性往往会导致吸附材料的CO₂捕集率降低甚至出现失效,也会造成捕集系统产生温降、压降等寄生损失,甚至形成设备腐蚀、吸附剂中毒等不利影响,最终额外能耗和成本大幅提高。为解决上述挑战,深入理解CO₂与H₂O共吸附过程的作用机制,据此开发成本合理、再生能耗低且对水气不敏感的高效CO₂吸附剂及吸附技术是实现湿气源下高效吸附碳捕集的重要途径。目前,由于分散在多个领域且各有侧重,关于H₂O对CO₂吸附影响的机制分析缺乏汇总与概括,难以形成相对统一的观点。本文针对CO₂与H₂O共吸附过程,从宏观与微观层面进行了详细综述。首先,基于共吸附机制的基础研究,依次介绍了竞争吸附、变湿吸附和呼吸效应领域的研究进展并进行了简要评价。其次,基于共吸附的应用研究,阐述了湿气源CO₂捕集技术的吸附剂研发与工艺改进两部分的现状及进展,也对不同湿气源下CO₂捕集水平进行了简要评价。最后,总结了目前研究中的不足之处并展望了未来的研究方向。本文将分散于各领域的CO₂与H₂O共吸附过程进行集中归纳、分析和对比,或可为湿气源碳捕集技术提供有效的指导。     

金属有机框架材料的制备及在吸附分离CO2中的应用

金属有机框架（MOFs）材料是当今的研究热点之一,是一类颇有潜力成为适用于CO₂吸附和分离的重要材料。本文从MOFs的发展及其所具有的特点、MOFs用于CO₂的吸附与分离所取得的突破性进展以及MOFs的传统合成及绿色制备方法三个方面展开论述。主要论述了MOFs适用于CO₂吸附的原理,及其相对于传统的CO₂吸附材料所具有的特点和优势,亦阐述了MOFs修饰与调变的方法。列出了MOFs用于单组分CO₂吸附及CO₂/CH₄、CO₂/N₂吸附分离的结果。同时,针对传统MOFs制备方法不适宜大规模CO₂捕集材料的生产,特别论述了机械化学合成法和新兴的潮湿矿物风化法,其均具有绿色化、无溶剂、低能耗和简单等特点,是一类较有研究价值和应用潜力的技术。随着温室效应和不可再生石化燃料的消耗等环境和能源问题的日趋严峻,研究及开发适用于CO₂捕集与封存技术的MOFs新材料迫在眉睫,且任重而道远。     

离子液体捕集CO2

CO₂是导致温室效应的最主要成分,因此碳捕集技术的研究受到学术界和产业界的高度重视。离子液体具有不挥发、不燃烧、热稳定性好、溶解能力强、结构和性质可调节并可循环使用等特性,在CO₂的吸收/分离领域展现了广阔的应用前景。本文系统地综述了近年来常规离子液体、功能化离子液体、支撑离子液体膜、聚合离子液体以及离子液体与分子溶剂的混合物在捕集CO₂方面的研究进展;讨论了离子液体的阳离子结构、阴离子类型、烷基链长度、阴/阳离子的氟化程度和功能化、离子液体的负载作用和聚合效应以及体系的温度和压力对CO₂选择性捕集性能的影响;分析了可能的捕集机理以及各种捕集方法的优点和缺点;提出了目前需要进一步研究的若干重要问题,并对其发展前景进行了展望。     

基于单原子催化剂的二氧化碳选择性转化

Industrial revolution has led to increased combustion of fossil fuels. Consequently, large amounts of CO₂ are emitted to the atmosphere, throwing the carbon cycle out of balance. Currently, the most effective method to reduce the CO₂ concentration is direct CO₂ capture from the atmosphere and pumping of the captured CO₂ deep underground or into the mid-ocean. The transformation of CO₂ into high-value chemicals is an attractive yet challenging task. In recent years, there has been much interest in the development of CO₂ utilization technologies based on electrochemical CO₂ reduction, photochemical CO₂ reduction, and thermal CO₂ reduction, and CO₂ valorization has emerged as a hot research topic. In electrochemical CO₂ reduction, the cathodic reaction is the reduction of CO₂ to value-added chemicals. The anodic reaction should be the oxygen evolution reaction, and water is the only renewable and scalable source of electrons and protons in this reaction. There is a plethora of research on the use of various metals to catalyze this reaction. Among these, Cu-based materials have been demonstrated to show unique catalytic activity and stability for the electrochemical conversion of CO₂ to valuable fuels and chemicals. Moreover, the solar-driven conversion of CO₂ into value-added chemical fuels has attracted great attention, and much effort is being devoted to develop novel catalysts for the photoreduction of CO₂, especially by mimicking the natural photosynthetic process. The key step in the photocatalytic process is the efficient generation of electron-hole pairs and separation of these charge carriers. The efficient separation of photoinduced charge carriers plays a crucial role in the final catalytic activity. Compared with CO₂ reduction via electrocatalysis and photocatalysis, thermal reduction is more attractive because of its potential large-scale application in the industry. Heterogeneous nanomaterials show excellent activity in the electrocatalytic, photocatalytic, and thermal catalytic conversion of CO₂. However, nanostructured materials have drawbacks on the investigation of the intrinsic activity of the active sites. In recent years, single-site catalysts have become popular because they allow for maximum utilization of the metal centers, show specific catalytic performance, and facilitate easy elucidation of the catalytic mechanism at the molecular level. Accordingly, numerous single-site catalysts were developed for CO₂ reduction to produce value-added chemicals such as CO, CH₄, CH₃OH, formate, and C₂₊ products. Value-added chemicals have also been synthesized with the aid of amines and epoxides. This review summarizes recent state-of-the-art single-site catalysts and their application as heterogeneous catalysts for the electroreduction, photoreduction, and thermal reduction of CO₂. In the discussion, we will highlight the structure-activity relationships for the catalytic conversion of CO₂ with single-site catalysts.     

BMIMBF4中2-氨基-3-氯-1,4-萘醌电化学捕获CO2的机理

利用循环伏安法（CV）和现场红外光谱电化学技术研究了2-氨基-3-氯-1,4-萘醌（ACNQ）在1-丁基-3-甲基咪唑四氟硼酸盐（BMIMBF₄）中电化学捕获CO₂的机理.研究结果表明,当体系中不存在CO₂时,ACNQ在BMIMBF₄中经历可逆的两步一电子过程;当体系中引入CO₂时,电化学还原过程中形成的二价阴离子（ACNQ^2-）作为亲核试剂,可攻击CO₂的亲电子碳中心,形成稳定的CO₂加合物.对电化学捕获CO₂的化学计量进行了评估,结果表明,1摩尔的ACNQ^2-可捕获1摩尔的CO₂.结合B3LYP方法在6-311++G^**水平上计算分析了反应中CO₂加合物可能的结构.     

离子液体介导CO2化学转化研究进展

The efficient utilization of carbon dioxide (CO₂) as a C1 feedstock is of great significance for green and sustainable development. Therefore, the efficient chemical conversion of CO₂ into value-added products has recently attracted a lot of research attention in recent years. The transformation of CO₂ generally requires high-energy substrates, specific catalysts, and harsh reaction conditions due to its high thermodynamic stability and kinetic inertness. Consequently, several efforts have been dedicated toward the development of high-performance catalysts and new reaction routes for CO₂ conversion over the last few decades. To date, many routes of convert CO₂ into value-added chemicals have been proposed, together with the development of heterogeneous and homogeneous catalysts. Among the advanced catalysts reported to date, ionic liquids (ILs) have been widely investigated and show great potential for the efficient, selective, and economical conversion of CO₂ into highly valuable products under mild conditions, even under ambient conditions. Some task-specific ILs have been designed with unique functional groups (e.g., —OH, —SO₃H, —NH₂, —COOH, and —C≡N), which can act as the solvent, absorbent, activating agent, catalyst, or cocatalyst to realize the transformation of CO₂ under metal-free and mild conditions. In addition, a variety of catalytic systems composed of ILs and metal catalysts have also been reported for the transformation of CO₂, in which the combination of the IL and metal catalyst is responsible for CO₂ conversion with high efficiency. In this review article, we summarize the recent advances in IL-mediated CO₂ transformation into chemicals prepared via C—O, C—N, C—S, C—H, and C—C bond forming processes. ILs that can chemically capture CO₂ with high capacity are first introduced, which can activate CO₂ via the formation of IL-based carbonates or carbamates, thus realizing the transformation of CO₂ under metal-free and mild conditions. Recent progress in IL-mediated CO₂ transformations to form carbonates and various kinds of N- and S-containing compounds (e.g., oxazolidinones, ureas, benzimidazolones, formamides, methylamines, benzothiazoles, and other chemicals) as well as CO₂ hydrogenation to give formic acid, methane, acetic acid, low-carbon alcohols, and hydrocarbons has been summarized in this review with a focus on the reaction routes, catalytic systems, and reaction mechanism. In these reactions, ILs can simultaneously activate the substrate via strong H-bonding in addition to activating CO₂, and the cooperative effects among the ionic and molecular species and metal catalysts accomplish the reactions of CO₂ with various kinds of substrates to afford a wide range of value-added chemicals. Finally, the shortcomings and perspectives of ILs are discussed. In short, IL-mediated CO₂ transformations provide green and effective routes for the synthesis of high-value chemicals, which may have great potential for a wide range of applications.     

二氧化碳多相催化加氢制C2及以上烃类和醇的研究进展

通过可再生能源得到的氢气将二氧化碳转化为高附加值的燃料和化学品,对于缓解全球变暖、改善生态环境和解决化石资源日益枯竭的难题具有重要的意义。通过加氢反应合成碳氢化合物,尤其是C₂₊烃类和含氧化合物愈来愈引起大家的研究兴趣。设计制备兼具二氧化碳活化和碳-碳键耦合的多功能催化剂仍然是一较大的挑战。本文总结了二氧化碳加氢合成长链烷烃、低碳烯烃、高级醇的最新研究进展,探讨了二氧化碳加氢所涉及的相关反应的热力学和动力学、反应机理和反应路径,并对现阶段报道的多相催化剂进行了归纳和分析,最后指出未来在二氧化碳加氢的多相催化过程中所面临的问题和发展方向。     

铋基二氧化碳还原电催化材料研究进展

二氧化碳（CO₂）作为一种经济、安全、可再生的碳资源化合物,其高效回收利用一直是全社会关注的焦点. 利用电化学方法,将CO₂还原转化生成一系列高附加值的化学品或燃料,对于缓解能源与环境双重压力具有重要的现实意义. 本论文介绍了电化学CO₂还原反应的基本原理与过程,综述了近年来铋基催化材料的发展现状,重点对这类催化材料的制备合成、结构调控、催化反应机理研究等方面进行了总结,最后对其未来发展方向进行了探讨与展望.     

基于纳米金属的增强效应在CO2电还原反应中的应用进展

将二氧化碳通过电化学方法转化为化工原料再利用,不仅可以有效缓减温室效应,而且可以实现自然界的碳循环,对绿色化学与可持续发展意义重大. 本文简要地介绍了二氧化碳电还原的优势及其基本反应原理并综述了近年来基于纳米金属催化剂的一系列活性增强策略的研究进展. 重点探究了合金效应、界面工程、协同效应、缺陷工程以及载体效应等对纳米金属电催化还原二氧化碳性能的影响及相关反应机理. 基于以上策略,提出未来开发面向工业化应用的二氧化碳电还原催化剂面临的挑战与前景.     

Carbonized Yolk-shell Metal-Organic Frameworks for Electrochemical Conversion of CO2 into Ethylene

With the excessive consumption of fossil fuels and the massive emission of CO₂, it has led to a series of environmental crises posing a serious threat to sustainable development. Electrochemical CO₂ reduction reaction (CO₂RR) to ethylene helps solve these serious environmental crises. Herein, we report the synthesis of a copper-based electrocatalyst by pyrolysis of yolk-shell structured HKUST-1 with partial substitution of trimesic acid by benzimidazole(nitrogen source). The electrocatalyst exhibits an ethylene Faradic efficiency(FE) of 25.8% and a partial ethylene current density of 23.7 mA/cm², in addition, the electrocatalyst can maintain stable performance during 10 h of electrolysis, which are all better than those of the electrocatalyst without nitrogen dopant. According to electrochemical measurements and X-ray photoelectron spectroscopy(XPS), we propose that the nitrogen dopant plays an effective role in stabilizing Cu(I) species and promoting CO₂ molecules activation, as well as suppressing the reduction of Cu(I) species during electrolysis. Eventually, the performance of the electrocatalyst toward CO₂RR is studied in a flow cell. This work provides a new route for the design of Cu-based electrocatalyst toward electrochemical CO₂ conversion into ethylene.     

Pd/C催化剂用于CO2电化学还原生成CO:Pd载量的影响

CO₂电化学还原反应可以将CO₂转化为燃料并同时实现再生能源的有效存储. 目前纳米结构的多相催化剂已经广泛应用于此反应,其中碳负载钯纳米粒子（Pd/C）表现出优异的CO₂电化学还原性能. 本工作研究了钯载量对于Pd/C催化剂结构以及其催化CO₂还原生成CO反应活性和选择性的影响. 不同载量的Pd/C催化剂通过液相还原方法制备,钯纳米粒子均匀地分散在碳载体上,载量并没有明显改变对纳米粒子的粒径. 在优选的电解质（0.1 mol·L^-1 KHCO₃）中,CO法拉第效率与载量呈现火山型曲线关系,-0.89 V时载量为20wt%的Pd/C催化剂达到最高的CO法拉第效率(91.2%). 生成CO的几何电流密度随着钯载量的增加而增加,但CO转换频率具有相反的趋势,载量为2.5wt%的Pd/C催化剂具有最高的转换频率. 这种载量对CO₂电化学还原反应活性和选择性的影响主要由活性位的数量、反应动力学、中间物种的稳定性以及反应物、中间物种和产物的传质过程等共同决定.     

CO_2熔盐电化学转化碳材料的电化学特性

基于对熔融碳酸盐体系中电化学还原CO_2所得碳材料(electrolytic-carbon,EC)的形貌、结构、组成的认识,以粉末微电极循环伏安法测试为基础,在稀溶液中对EC的本征电化学行为进行了考察,以揭示这类碳材料的界面电化学特性。实验发现,在典型条件(450°C、4.5 V槽压)下制备的电解碳(450°C-4.5 V-EC)的伏安行为有别于多壁碳纳米管、石墨烯、石墨、乙炔黑等常见碳材料,在负电位区表现出显著的"双电层充放电响应迟滞"现象。通过考察溶液pH值、电位扫描速率、阴阳离子种类对这一现象的影响,发现pH和电解液组成都不影响这一现象的出现;电解液浓度提高和低扫描速率时滞后现象减弱,表明迟滞充放电是这类碳材料的本征特性,与其表面含氧官能团及其对阳离子的特性吸附密切相关。实验进一步研究了不同电解条件下制备的EC所展现的电化学特性吸附及电容性质,发现随着熔盐温度的升高,EC对电解液中阳离子的特性吸附能力降低,而相同温度不同槽压下制备的EC特性吸附能力相近,表现出相似的电容特性,这与EC的含氧量和比表面积有关。电解碳所展现的独特电容特性对其潜在的应用或可提供有价值的线索和指导。