Understanding Bridging Sites and Accelerating Quantum Efficiency for Photocatalytic CO_(2) Reduction

We report a novel double-shelled nanoboxes photocatalyst architecture with tailored interfaces that accelerate quantum efficiency for photocatalytic CO_(2) reduction reaction(CO_(2)RR)via Mo–S bridging bonds sites in S_(v)–In_(2)S_(3)@2H–MoTe_(2).The X-ray absorption near-edge structure shows that the formation of S_(v)–In_(2)S_(3)@2H–MoTe_(2) adjusts the coordination environment via interface engineering and forms Mo–S polarized sites at the interface.The interfacial dynamics and catalytic behavior are clearly revealed by ultrafast femtosecond transient absorption,time-resolved,and in situ diffuse reflectance–Infrared Fourier transform spectroscopy.A tunable electronic structure through steric interaction of Mo–S bridging bonds induces a 1.7-fold enhancement in S_(v)–In_(2)S_(3)@2H–MoTe_(2)(5)photogenerated carrier concentration relative to pristine S_(v)–In_(2)S_(3).Benefiting from lower carrier transport activation energy,an internal quantum efficiency of 94.01%at 380 nm was used for photocatalytic CO_(2)RR.This study proposes a new strategy to design photocatalyst through bridging sites to adjust the selectivity of photocatalytic CO_(2)RR.

CO_(2)电弧等离子加热器电热特性研究

对管状阴极轴线式CO_(2)电弧等离子加热器的电热特性进行了实验研究,得到了电流、气体流量、励磁电流和前电极长径比对电弧加热器的伏安特性和热效率的影响规律。采用相似理论模型,对实验数据进行回归分析,得到了加热器伏安特性和热损失系数的近似表达式。研究结果发现,CO_(2)气体流量和电弧电流对加热器的伏安特性和热效率都具有显著的影响,前电极的长径比和励磁电流则只对热效率具有影响。电弧加热器伏安特性和热损失系数的回归公式计算值与实验数据一致性较好,伏安特性回归误差<10.0%,热损失系数回归误差<18.2%。

基于高干度泡沫实验的非均质咸水层CO_(2)封存能力分析

CO_(2)咸水层封存是实现“碳中和”目标的一项重要技术手段。高干度泡沫不仅能更好地控制CO_(2)流度而且还能适应地层的非均质性,明显提高了咸水层的空间利用效率。为探究高干度CO_(2)泡沫在非均质咸水层中的调剖效果与CO_(2)封存能力,利用自行设计的高温高压驱替实验装置,进行了不同渗透率级差的并联岩心CO_(2)泡沫驱室内实验研究,分析了驱替过程中岩心的气液产出情况与CO_(2)饱和度的变化规律,指出了不同渗透率级差非均质岩心模型的碳封存效果与机理。研究结果表明:①与CO_(2)气驱相比高干度泡沫驱用于CO_(2)咸水层埋存具有更大优势,当岩心渗透率级差介于2.6~10.8时,泡沫均能有效封堵高渗透岩心,使阻力因子维持在36左右,增大了驱替压差与低渗透岩心的产气、产液速度;②岩心中气相饱和度与渗透率存在一定关系,当岩心的渗透率小于2450 mD时,最高气相饱和度随渗透率增加而增大,当渗透率超过2450 mD时,岩心最高气相饱和度在80%左右;③采用高干度泡沫驱可以有效扩大岩心中CO_(2)封存量,渗透率级差为4时,泡沫驱的CO_(2)封存体积较气驱增长219%,当渗透率级差扩大至10.8,CO_(2)封存量能始终维持在较高水平。结论认为,咸水层条件下CO_(2)泡沫驱替实验探究了CO_(2)封存能力变化,提供了非均质储层提高碳封存效率的实验认识,可为非均质咸水层中CO_(2)的地质封存技术优化提供参考和借鉴。

MDEA基相变吸收剂筛选及其CO_(2)捕集性能

为了达到快速筛选相变吸收剂的目的,基于汉森溶解度参数理论,以N-甲基二乙醇胺(MDEA)为主吸收剂,有机溶剂为分相促进剂,水为溶剂,快速筛选出一种新型相变吸收剂——MDEA/聚乙二醇二甲醚(NHD)/H2O。热重分析(TGA)测试了相变吸收剂的热稳定性,CO_(2)吸收、解吸试验探究了相变吸收剂的CO_(2)吸收性能、解吸性能及循环再生能力。1 HNMR测试了相变前后物质的分布情况。结果表明,MDEA/NHD/H_(2)O相变吸收剂相比质量分数30%乙醇胺(MEA)吸收剂及文献已报道的MDEA/正丁醇/H_(2)O相变吸收剂具有最高的热稳定性。NHD作为分相促进剂的同时可促进CO_(2)在相变吸收剂中的溶解,MDEA/NHD/H_(2)O相变吸收剂发生液-液分相需要NHD和H_(2)O同时存在。25℃时,质量比为3∶5∶2的MDEA/NHD/H_(2)O相变吸收剂具有最高CO_(2)吸收容量为1.0695 mol/L。所开发的相变吸收剂可将送至解吸单元的解吸液体积降至42%。在解吸温度90℃时,CO_(2)解吸效率达98.96%。在25℃下吸收,90℃下热解吸,经10次吸收、解吸循环再生试验,质量比为3∶5∶2的MDEA/NHD/H_(2)O相变吸收剂的CO_(2)总循环容量为9.2604 mol/L,相比于质量分数30%MEA吸收剂、30%MDEA吸收剂及MDEA/正丁醇/H_(2)O相变吸收剂具有最高的CO_(2)循环能力。^(1)HNMR测试结果表明该相变吸收剂的上液相主要成分为NHD,为贫液相。下液相主要成分为MDEA和MDEAH^(+),为富液相。

改性凹凸棒土的制备及其催化解吸CO_(2)性能研究

为进一步降低碳捕集技术成本,提高CO_(2)解吸效率,制备了一种低成本的金属改性凹凸棒土(ATP)固体酸催化剂,通过调控催化剂酸位丰度促进胺溶剂再生速率。结果表明,ATP-Zr可将CO_(2)解吸量和解吸速率分别提升13.8%和42%。此外,对合成的催化剂进行了表征分析以及成型工艺的研究,可为固体酸催化剂制备及低能耗CO_(2)捕集技术的工业化应用提供理论支撑。

MAP-DMSO-PMDETA三元相变吸收剂的CO_(2)捕集性能

以仲胺3-甲基胺基-1-丙醇(MAP)为主吸收剂、二甲基亚砜(DMSO)为有机稀释剂、五甲基二乙烯三胺(PMDETA)为辅助吸收剂,制备了新型MAP-DMSO-PMDETA三元相变吸收剂,考察了其相变行为和CO_(2)吸收性能。实验结果表明:在MAP、DMSO与PMDETA的质量比为3∶6∶11,吸收温度为40℃,CO_(2)体积分数为10%,进气流量为1.25 L/min的优化条件下,吸收饱和后发生液液分相,吸收剂负载量为0.79 mol/kg,吸收负荷为0.47 mol/mol(以MAP计),富相的体积分数为45.1%,并富集了95.1%的CO_(2),而黏度仅为11.83 mPa·s;该三元相变吸收剂不仅解吸性能优异,同时循环稳定性良好,经5次吸收-解吸循环,解吸负荷稳定在0.34 mol/mol(以MAP计)左右,解吸效率可达69.4%。

不同类型生物炭对CO_(2)吸附性能及其机理

本研究以5种生物质为原料制备了生物炭,并对其进行理化表征,考察了生物炭对CO_(2)的吸附性能及机理。结果表明,椰壳(YK)、松木(SM)生物炭的比表面积是玉米芯(YM)、芦苇秆(LW)、椰衣(YY)生物炭的1.99~2.90倍。YK、SM对CO_(2)的吸附量(108.78~118.89 mg/g)高于YM、LW、YY(95.33~105.55 mg/g)。此外,YK中较高的S含量(2.17%)与碱度对CO_(2)吸附也起着促进作用。研究发现,生物炭的比表面积、孔径、碱度、官能团均是影响CO_(2)吸附的重要因素,当孔隙差异明显时,孔隙结构对CO_(2)吸附的影响会掩盖碱度带来的差异。Avrami模型和Langmuir模型可以较好地拟合生物炭对CO_(2)的吸附过程,表明CO_(2)在生物炭上的吸附以单层吸附为主。生物炭吸附CO_(2)是以物理吸附为主伴有化学吸附作用的过程,且受温度影响较大,当温度从0℃升高到65℃时,生物炭对CO_(2)的吸附量降低了73.42%~77.14%。经过5次CO_(2)吸脱附循环后,生物炭仍具有较高的可重复使用性(85.26%~98.41%),这表明生物炭具有良好的CO_(2)捕集潜力。

CO_(2)与绿氢合成甲醇的过程模拟及储能性能分析

文章模拟了CO_(2)与绿氢合成甲醇的过程,提出了CO_(2)储能密度指标,研究了多个参数对甲醇储能性能的影响。研究结果表明:系统能效和甲醇能量产率随着电解水效率、单程CO_(2)转化率、电解水压力和CO_(2)初始压力的升高而升高,随着甲醇合成压力的升高而降低;CO_(2)储能密度随以上参数的变化趋势与系统能效和甲醇能量产率相反;电解水效率和单程CO_(2)转化率是敏感关键的参数;在最优组合工况下,基于甲醇高位和低位热值的系统能效分别为68.0%和59.6%,CO_(2)储能密度为6.07 k W·h/kg,能量产率为0.108 kg/(k W·h),表明以CO_(2)为原料的电制甲醇的系统能效不够理想,但储能密度优势显著。

致密砂岩气藏注CO_(2)提高天然气采收率微观机理

中国致密砂岩气藏资源储量丰富,复杂的气水渗流关系和气水同产特征制约了单井产能的发挥和天然气采收率提高,注CO_(2)是提高气藏采收率(EGR)和实现碳埋存的双赢途径。为明确致密砂岩气藏CO_(2)驱替微观渗流和提高天然气采收率机理,指导致密砂岩气藏CO_(2)-EGR方案设计,基于格子玻尔兹曼方法(LBM)建立了孔隙尺度多相多组分流动模型,揭示了致密砂岩气藏储层微观气水分布特征和CO_(2)-EGR的微观渗流机理,并明确了CO_(2)-EGR的主控因素。研究结果表明:①驱动压差显著影响了致密砂岩气藏的气水微观分布和水锁程度,使得气水流动能力和气水相对渗透率特征不同;②CO_(2)-EGR微观渗流过程包括气水两相的非混相驱替和CO_(2)-CH_(4)的混相驱替,对应EGR机理为分别受生产压差和地层压力控制的黏性驱替和混相扩散;③注入的CO_(2)可有效缓解水锁现象和贾敏效应,与CH_(4)良好的混相能力能促进沟通分散气泡,微观驱气效率可达42%~94%;④含水饱和度、孔隙结构和驱动压差显著影响微观驱气的作用机制和驱气效率的改善幅度。结论认为,在进行致密砂岩气CO_(2)-EGR的方案设计时,可优先考虑中—低含水饱和度的区块作为试验靶区,并根据靶区储层孔隙结构特征,优化不同注气阶段的注采参数,可充分发挥CO_(2)对CH_(4)的黏性驱替和混相扩散作用。

太阳能熔融盐供热的CH_(4)-CO_(2)重整热化学储能反应热力学分析

以太阳能熔融盐为载热工质的CH_(4)-CO_(2)重整热化学反应是极具应用潜力的热化学储能技术,为探讨工业级CH_(4)-CO_(2)重整储能反应器在不同操作条件下热力学性能的变化规律,建立了基于太阳能熔融盐供热的CH_(4)-CO_(2)重整储能反应器的二维拟均相数学模型,通过数值模拟分析了反应混合物进口温度(T_(in))和进口摩尔流率(F_(tot,in))对反应器内温度、反应转化率和热化学储能效率等的影响规律。结果表明:当进口温度较高时(T_(in)=823 K),转化管内温度沿转化管轴向表现为先降低后升高的变化趋势;当进口温度较低时(T_(in)=573K),转化管内温度沿转化管轴向单调升高;T_(in)=573K下,随着进口摩尔流率的增大,反应转化率单调减小,化学储能效率呈现先增大后减小的变化趋势;在进口摩尔流率相同的条件下,进口温度越高,反应转化率和化学储能效率越大;T_(in)=823 K下,随着进口摩尔流率的增大,显热储能效率和热损失率减小,化学储能效率增大;F_(tot,in)=1 mol/s下,随着反应混合物进口温度的升高,化学储能效率与热损失率增大,显热储能效率减小。

异氟尔酮二胺-水二元固-液相变吸收剂捕集CO_(2)机制

固-液相变吸收剂在CO_(2)负荷调控下可发生相变形成固体产物,具有易分离、操作简便的优势,但现有体系大多需有机分相剂调控才能发生固液相变,存在分相剂易挥发损耗、富液黏度大等瓶颈。本研究构建了异氟尔酮二胺(IPDA)-水二元固-液相变吸收体系,无需分相剂,水相溶液吸收CO_(2)后即可发生固液相变。研究表明,1.00 mol·L^(-1)IPDA水溶液在313.15 K下饱和吸收负荷高达0.85 mol CO_(2)·mol^(-1),吸收产物为白色晶体粉末且富集在溶液下层,富液体积占总溶液体积的43.60%,而CO_(2)富集率达93.98%,此时,上层贫相黏度为1.08 mPa·s。富相固体产物分离熔融后在393.15 K温度条件下解吸60 min,再生效率为98.31%。经5次循环吸收-解吸,再生容量仍保持初始容量的80%以上,具有良好的重复利用性。^(13)C核磁共振(NMR)表征分析表明,IPDA与CO_(2)反应生成IPDA-氨基甲酸盐与碳酸氢盐,大多聚集在富相中,仅少量氨基甲酸盐溶于贫相中。解吸完成后,样品未见CO_(2)产物峰,进一步证明了IPDA-H_(2)O可完全解吸。量子化学计算证明,吸收前IPDA与水偶极矩接近,极性相近可互溶,吸收后形成的产物偶极矩低、极性小,产物间的分子内氢键高于产物和水的氢键,产物晶格能增加。因此,产物从溶液中析出,无需分相剂调控,即可在水中发生固液相变。

非共沸工质CO_(2)/R1234yf商超增压制冷系统性能分析

为满足商超制冷领域系统能效提升和制冷剂替代的需求,提出了非共沸工质CO_(2)/R1234yf商超增压制冷系统,通过建立热力学模型,与纯CO_(2)商超增压制冷系统进行对比。结果表明:CO_(2)/R1234yf商超增压制冷系统可在最优的CO_(2)质量分数(0.94)及最优排气压力(8.81 MPa)下获得最大COP(1.40);CO_(2)/R1234yf商超增压制冷系统COP与纯CO_(2)系统相比具有显著提升,环境温度为35℃时,提升7.25%;CO_(2)/R1234yf商超增压制冷系统APF提升率为2.68%~4.72%,系统APF随典型城市所处纬度的增加而增大。CO_(2)/R1234yf商超增压系统(火用)效率随CO_(2)质量分数的增加呈先增后减趋势,CO_(2)质量分数为0.95时获得最高(火用)效率,为0.18,相比纯CO_(2)系统提升4.62%。

分子模拟CH_(4)和CO_(2)在方解石-白云石岩层的吸附机理

为揭示碳酸盐岩层页岩气的富集特征和开采机理,采用巨正则蒙特卡洛、分子动力学和密度泛函耦合方法探究了不同地质埋深条件下CH_(4)和CO_(2)在方解石-白云石岩层的吸附机理。研究表明,CO_(2)在方解石-白云石岩层的吸附热为38~48 kJ/mol,其在白云石表面的吸附能大于44 kJ/mol,从理论上证实CO_(2)在白云石表面可形成化学吸附。白云石表面CO_(2)的吸附密度峰大于方解石表面,白云石更有利于CO_(2)的地质封存。随着地质埋深的增加,纯组分CO_(2)和CH_(4)在方解石-白云石岩层的超额吸附量分别在600、1600 m会出现一个极大值;而CH_(4)的总负载量随着地质埋深的增加先迅速增加,在3000 m后增长缓慢。因此,CO_(2)在方解石-白云石岩层地质封存的有利埋深约在600 m,CH_(4)的富集有利区位于3000 m以深。CH_(4)的采收率与CO_(2)的注入压力成正比,并随着地质埋深的增加先增加,当地质埋深大于1000 m后,采收率趋于平稳。该研究为碳酸盐岩层页岩气的储量评估和CO_(2)强化页岩气开采技术的应用提供重要理论依据。

电化学反应性捕集CO_(2)研究进展与挑战

CO_(2)捕集是控制温室气体排放的关键技术之一,电化学CO_(2)还原是关闭人工碳循环的有效途径,但CO_(2)捕集和电化学CO_(2)还原过程均为能源密集型过程。过去的研究将两者视为相互独立的技术和科学领域进行发展。通过直接电解捕集介质(如胺基富液和碳酸氢盐),将上游的碳捕集和下游的电化学还原过程进行集成耦合,可以避免高能耗的捕获介质再生和CO_(2)释放环节,避免CO_(2)的运输和存储操作,降低整体工艺的运行成本,提升整个碳循环的能量效率和经济效益,为节约能源和经济高效地捕集利用CO_(2)提供了一个潜在的解决方案。总结了目前电化学反应性捕集CO_(2)的研究进展,论述了在电极和电解质方面取得的成果,讨论了影响集成电解效率的限制因素,并分析了各类因素的潜在影响机制和可能的反应路径。最后,强调了直接电化学还原捕集介质领域的主要挑战和机遇,并对未来耦合碳捕集与电化学利用过程的发展进行展望。

A Research Progress of CO_(2)-Responsive Plugging Channeling Gels

In the heterogeneous reservoirs,CO_(2) flooding easily leads to CO_(2) gas channeling,which can seriously affect sweeping efficiency and reduce oil recovery.After thoroughly investigating the advantages and shortcomings of various CO_(2) plugging technologies,this paper focuses on the feasibility of improving conventional water-alternating gas(WAG)through CO_(2)-responsive gel materials.Based on the different chemical reaction mechanisms between the unique chemical structure and CO_(2),changes in the material’s physical and chemical properties can respond to CO_(2).The feasibility of utilizing these property changes for CO_(2)-responsive plugging is explored.Various CO_(2)-responsive gels and gel nanoparticles have been extensively researched in different fields,such as energy,medicine,and biology.This paper surveys the molecular structures,chemical compositions,response mechanisms,and changes of these CO_(2)-responsive gels,aiming to draw insights into the carbon dioxide-enhanced oil recovery(CO_(2)-EOR)field.Finally,the key issues and future development direction of CO_(2)-responsive plugging gels were analyzed.

闭式跨临界CO_(2)热泵烘干系统最优工况研究

目的对跨临界CO_(2)热泵驱动的闭式干燥系统展开理论研究,得到CO_(2)闭式热泵中最优工况的计算方法和原理。方法通过建立CO_(2)循环与空气循环热力学耦合的数学模型,计算干燥循环中空气的温度、焓值、相对湿度、含湿量,以及跨临界CO_(2)热泵系统中工质的温度、压力、焓值等参数。通过调整冷凝干燥后空气温度,以热泵烘干系统的COP为评价依据,探究空气循环与CO_(2)热泵循环的耦合机理。结果获得了CO_(2)循环系统最优排气压力随闭式空气循环系统在不同工况下的变化规律,并基于所建立的计算程序,获得了典型工艺参数下的热泵系统的热力学参数,为关键设备(风机、换热器、压缩机等)选型及系统控制方法提供了理论依据。结论研究表明,在CO_(2)热泵冷却器出口状态为临界状态时,系统的COP达到最优。

燃煤电厂CO_(2)捕集的减排效率研究与展望

为了客观评价不同CO_(2)捕集技术的能耗水平,判别CO_(2)捕集技术的有效性和经济性,提出减排效率概念和计算模型。CO_(2)减排效率表示某种CO_(2)捕集技术的有效减排能力,即捕集单位CO_(2)所发生的CO_(2)有效减排量,减排效率模型对CO_(2)捕集技术的能耗进行归集和平准化计算,其值越大表明减排效果越佳。利用减排效率模型测算,目前我国燃煤电厂CO_(2)捕集技术的减排效率理论极值为98%,燃烧前、燃烧中和燃烧后捕集技术的减排效率分别达到80%、70%和58%~68%。经工程应用实践验证,减排效率模型能满足评价要求。最后对CO_(2)捕集技术的发展进行了展望,认为未来随着捕集技术的不断进步和创新,CO_(2)减排效率将超过90%。

CO_(2)浓度升高对农田生态系统水分利用效率的影响效应——基于气候箱控制性试验的Meta分析

选取1985—2020年21篇与气候箱控制性试验有关的文献,利用Meta分析法研究CO_(2)浓度升高对农田生态系统水分利用效率(WUE)的影响。结果显示,在气候箱的控制下CO_(2)浓度升高对水分利用效率有正面影响,增加的比例为20%,对碳积累和蒸散发分别有正面和负面的效应,影响的效应分别为34%和-4%,但都存在显著的异质性(P<0.05)。研究还发现,CO_(2)浓度升高对WUE的影响效应与对碳积累的影响效应有显著的正相关关系(P<0.05),而与对蒸散发的影响效应没有显著的相关关系(P>0.05)。异质性分析结果显示,CO_(2)浓度升高对WUE的影响效应在不同物种间具有显著的差异,其中对大豆和番茄的影响效应显著高于对小麦的影响效应(P<0.05)。此外,CO_(2)浓度升高对WUE的影响效应与光照强度、温度和土壤相对含水量都有显著的相关关系(P<0.05),其中与光照强度有负相关关系,与温度和土壤含水量有正相关关系;而与CO_(2)富集程度没有显著的相关关系。

A multiphysical-geochemical coupling model for caprock sealing efficiency in CO_(2) geosequestration

Precipitation or dissolution due to geochemical reactions has been observed in the caprocks for CO_(2) geosequestration.Geochemical reactions modify the caprock sealing efficiency with self-limiting or self-enhancement.However,the effect of this modification on the caprock sealing efficiency has not been fully investigated through multiphysical-geochemical coupling analysis.In this study,a multiphysical-geochemical coupling model was proposed to analyze caprock sealing efficiency.This coupling model considered the full couplings of caprock deformation,two-phase flow,CO_(2) concentration diffusion,geochemical reaction,and CO_(2) sorption.The two-phase flow only occurs in the fracture network and the CO_(2) may partially dissolve into water and diffuse through the concentration difference.The dissolved CO_(2) has geochemical reactions with some critical minerals,thus altering flow channels.The CO_(2) in the fracture network diffuses into matrix,causing the matrix swelling.This fully coupling model was validated with a penetration experiment on a cement cube and compared with two other models for CO_(2) storage plumes.Finally,the effects of geochemical reactions on penetration depth and pore pressure were studied through parametric study.The numerical simulations reveal that the coupling of geochemical reactions and matrix diffusion significantly affect the caprock sealing efficiency.Geochemical reactions occur at a short time after the arrival of CO_(2) concentration and modify the fracture porosity.The CO_(2) diffusion into the matrix requires a much longer time and mainly induces matrix swelling.These effects may produce selfenhancement or self-limiting depending on the flow rate in the fracture network,thus significantly modifying caprock sealing efficiency.

Meta-analysis of CO_(2) conversion,energy efficiency,and other performance data of plasma-catalysis reactors with the open access PIONEER database

This paper brings the comparison of performances of CO_(2)conversion by plasma and plasma-assisted catalysis based on the data collected from literature in this field,organised in an open access online database.This tool is open to all users to carry out their own analyses,but also to contributors who wish to add their data to the database in order to improve the relevance of the comparisons made,and ultimately to improve the efficiency of CO_(2)conversion by plasma-catalysis.The creation of this database and database user interface is motivated by the fact that plasma-catalysis is a fast-growing field for all CO_(2)conversion processes,be it methanation,dry reforming of methane,methanolisation,or others.As a result of this rapid increase,there is a need for a set of standard procedures to rigorously compare performances of different systems.However,this is currently not possible because the fundamental mechanisms of plasma-catalysis are still too poorly understood to define these standard procedures.Fortunately however,the accumulated data within the CO_(2)plasma-catalysis community has become large enough to warrant so-called“big data”studies more familiar in the fields of medicine and the social sciences.To enable comparisons between multiple data sets and make future research more effective,this work proposes the first database on CO_(2)conversion performances by plasma-catalysis open to the whole community.This database has been initiated in the framework of a H_(2)0_(2)0 European project and is called the“PIONEER Data Base”.The database gathers a large amount of CO_(2)conversion performance data such as conversion rate,energy efficiency,and selectivity for numerous plasma sources coupled with or without a catalyst.Each data set is associated with metadata describing the gas mixture,the plasma source,the nature of the catalyst,and the form of coupling with the plasma.Beyond the database itself,a data extraction tool with direct visualisation features or advanced filtering functionalities has been developed and is available online to the public.The simple and fast visualisation of the state of the art puts new results into context,identifies literal gaps in data,and consequently points towards promising research routes.More advanced data extraction illustrates the impact that the database can have in the understanding of plasma-catalyst coupling.Lessons learned from the review of a large amount of literature during the setup of the database lead to best practice advice to increase comparability between future CO_(2)plasma-catalytic studies.Finally,the community is strongly encouraged to contribute to the database not only to increase the visibility of their data but also the relevance of the comparisons allowed by this tool.