谈CO_2化学转化研究进展
摘要
近年来,CO_2的资源化利用成为了活跃的研究领域。如何将CO_2转化成附加值较高的燃料和化学品,已经成为21世纪的重大科研课题,在CO_2资源化利用过程中如何将二氧化碳高效活化又是重中之重。对于CO_2转化策略,讨论了太阳能转化、等离子转化技术、电化学还原、催化转化和各新技术协同催化技术在CO_2活化转化中的应用进展,并展望了CO_2转化发展趋势。
引文
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[2]Nigara Y,Cales B.Production of CO by direct thermal splitting of CO2at high temperature[J].Bull Chem Soe JPn,1986(59):1997-2002.
[3]刘树森,朱继宇,张志磊,等.CO2甲烷化研究进展[J].工业催化,2018,26(1):1-12.
[4]Aziz M A A,Jalil A A,Triwahyono S,et al.CO2metha nation over heterogeneous catalysts:recent progress and futureprospects[J].Green Chem,2015(17):2647-2663.
[5]蒋青青,童金辉,陈真盘,等.太阳能光热化学分解CO2和H2O的研究进展[J].中国科学:化学,2014,44(12):1834-1848.
[6]Greg P S,Aldo S.Photochemical and thermochemical[J].Ind Eng Chem Res,2012,51(37):11828-11840.
[7]Romero M,Steinfeld A.Concentrating solar thermal power and thermochemical fuels[J].Energy Environ Sci,2012(5):9234-9245.
[8]Chen G,Britun N,Godfroid T,et al.An overview of CO2conversion in a microwave discharge:the role of plasmacatalysis[J].J Phys D:Appl Phys,2017(50):84001.
[9]朱斌.火花放电等离子体中甲烷的CO2重整与复合复整[D].大连:大连理工大学,2013.
[10]黄秋实,兰俐颖,王安杰,等.二氧化碳甲烷化反应中等离子体与Ni/ZSM-5催化剂的协同作用[J].石油化工,2017,46(11):1355-1360.
[11]吴帆.等离子体法分解CO2的反应动力学研究[D].大连:大连理工大学,2017.
[12]Kortlever R,Peters I,Koper S,et al.Electrochemical CO2reduction to formic acid at low over-potential and with high faradaic efficiency on carbon supported bimetallic Pd-Pt nanoparticles[J].ACS Catal,2015(5):3916-3923.
[13]白晓芳,陈为,王白银,等.二氧化碳电化学还原的研究进展[J].物理化学学报,2017,33(12):2388-2403.
[14]Qiao J,Liu Y,Hong F,et al.A review of catalysts for the electro-reduction of carbon dioxide to produce low-carbon fuels[J].Chem Soc Rev,2013,43(2):631-675.
[15]李亚楠.纳米氧化锡催化剂及其膜电极的制备及CO2电催化还原性能研究[D].上海:东华大学,2017.
[16]Hollingsworth N,Taylor SFR,Galante M T,et al.Reduction of carbon dioxide to formate at low over-potential using a super base ionic liquid[J].Angew Chem Int Ed,2015,54(47):14164-14168.
[17]冯建鹏,张香平,尚大伟,等.离子液体中电化学还原CO2研究评述与展望[J].化工学报,2018,69(1):69-75.
[18]景维云,毛庆,石越,等.CO2电催化还原制烃类产物的研究进展[J].化工学报,2017,36(6):2150-2157.
[19]Li K,An X,Park K,et al.A critical review of CO2photo conversion:Catalysts and reactors[J].Catalysis Today,2014(224):3-12.
[20]张渊.光催化剂微纳结构调控及应用于二氧化碳光[D].南京:南京大学,2017.
[21]王尔超,王加跑,曹先婷,等.二氧化碳的化学转化方法研究进展[J].杭州师范大学学报(自然科学版),2016,15(5):509-513.
[22]朱凯建,罗文俊,关中杰,等.光电化学分解水电池的电极性能提高方法及光阴极研究进展[J].电化学,2016,22(4):368-381.
[23]Jackson P,Hariskos D,Lotter E,et al.New world record efficiency for Cu(In,Ga)Se2thin-film solar cells beyond 20%[J].Progress in Photovoltaics,2011,19(7):894-897.
[24]Kumar B,Llorente M,Froehlich J,et al.Photochemical and photoelectrochemical reduction of CO2[J].Annu Rev Phys Chem,2012(63):541-569.
[25]Wei J,Ge Q J,Yao R W,et al.Directly converting CO2into a gasoline fuel[J].Nat Commun,2017:15174.
[26]Gao P,Li S G,Bu X N,et al.Direct conversion of CO2into liquid fuels with high selectivity over a bifunctional catalyst[J].Nature Chem,2017:2794.
[27]于伟超.微波诱导碳基催化剂催化甲烷裂解及重整制氢的实验研究[D].上海:东华大学,2014.
[28]Navarrete A,Centi G,Bogaerts A,et al.Harvesting renewable energy for carbon dioxide catalysis[J].Energy Technol,2017(5):796-811.
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