Citation: | GUO Shuai, FENG Likui, YU Zhiyong, XU Di, LIU Kaidi, SONG Xiaoning, CHENG Yijie, CAO Qiuyang, WANG Guanghui, DING Mingyue. Effects of preparation methods on the performance of InZr/SAPO-34 composite catalysts for CO2 hydrogenation to light olefins[J]. Journal of Fuel Chemistry and Technology. doi: 10.1016/S1872-5813(24)60433-0 |
[1] |
ÁLVAREZ A, BANSODE A, URAKAWA A, et al. Challenges in the greener production of formates/formic acid, methanol, and DME by heterogeneously catalyzed CO2 hydrogenation processes[J]. Chem Rev,2017,117(14):9804−9838. doi: 10.1021/acs.chemrev.6b00816
|
[2] |
KONDRATENKO E V, MUL G, BALTRUSAITIS J, et al. Status and perspectives of CO 2 conversion into fuels and chemicals by catalytic, photocatalyticand electrocatalytic processes[J]. Energy Environ Sci, 2013, 6(11): 3112−3135.
|
[3] |
王林祥, 常敏. 全球乙烯供需分析及预测[J]. 世界石油工业,2021,28(5):54−61.
WANG Linxiang, CHANG Min. Analysis and forecast of global ethylene supply and demand[J]. World Petro Ind,2021,28(5):54−61.
|
[4] |
马龙. 全球丙烯供需分析与预测[J]. 世界石油工业,2021,28(5):47−53.
MA L. Global propylene supply and demand analysis and forecast[J]. World Petro Ind,2021,28(5):47−53.
|
[5] |
ZHOU W, CHENG K, KANG J, et al. New horizon in C1 chemistry: Breaking the selectivity limitation in transformation of syngas and hydrogenation of CO2 into hydrocarbon chemicals and fuels[J]. Chem Soc Rev,2019,48(12):3193−3228. doi: 10.1039/C8CS00502H
|
[6] |
WANG D, XIE Z, POROSOFF M D, et al. Recent advances in carbon dioxide hydrogenation to produce olefins and aromatics[J]. Chem,2021,7(9):2277−2311. doi: 10.1016/j.chempr.2021.02.024
|
[7] |
XU Y, ZHAI P, DENG Y, et al. Highly selective olefin production from CO2 hydrogenation on iron catalysts: a subtle synergy between manganese and sodium additives[J]. Angew Chem Int Ed,2020,132(48):21920−21928. doi: 10.1002/ange.202009620
|
[8] |
LI Z, WANG J, QU Y, et al. Highly selective conversion of carbon dioxide to lower olefins[J]. ACS Catal,2017,7(12):8544−8548. doi: 10.1021/acscatal.7b03251
|
[9] |
GAO P, DANG S, LI S, et al. Direct production of lower olefins from CO2 conversion via bifunctional catalysis[J]. ACS Catal,2018,8(1):571−578. doi: 10.1021/acscatal.7b02649
|
[10] |
WANG S, ZHANG L, WANG P, et al. Highly effective conversion of CO2 into light olefins abundant in ethene[J]. Chem,2022,8(5):1376−1394. doi: 10.1016/j.chempr.2022.01.004
|
[11] |
SUN K, FAN Z, YE J, et al. Hydrogenation of CO2 to methanol over In2O3 catalyst[J]. J CO2 Util,2015,12:1−6. doi: 10.1016/j.jcou.2015.09.002
|
[12] |
MARTIN O, MARTÍN A J, MONDELLI C, et al. Indium oxide as a superior catalyst for methanol synthesis by CO2 hydrogenation[J]. Angew Chem Int Ed,2016,128(21):6369−6373. doi: 10.1002/ange.201600943
|
[13] |
DANG S, QIN B, YANG Y, et al. Rationally designed indium oxide catalysts for CO2 hydrogenation to methanol with high activity and selectivity[J]. Sci Adv,2020,6(25):eaaz2060. doi: 10.1126/sciadv.aaz2060
|
[14] |
LI K, CHEN J G. CO2 hydrogenation to methanol over ZrO2-containing catalysts: insights into ZrO2 induced synergy[J]. ACS Catal,2019,9(9):7840−7861. doi: 10.1021/acscatal.9b01943
|
[15] |
FREI M S, MONDELLI C, CESARINI A, et al. Role of zirconia in indium oxide-catalyzed CO2 hydrogenation to methanol[J]. ACS Catal,2019,10(2):1133−1145.
|
[16] |
YANG C, PEI C, LUO R, et al. Strong electronic oxide-support interaction over In2O3/ZrO2 for highly selective CO2 hydrogenation to methanol[J]. J Am Chem Soc,2020,142(46):19523−19531. doi: 10.1021/jacs.0c07195
|
[17] |
YE J, LIU C, MEI D, et al. Active oxygen vacancy site for methanol synthesis from CO2 hydrogenation on In2O3 (110): A DFT study[J]. ACS Catal,2013,3(6):1296−1306. doi: 10.1021/cs400132a
|
[18] |
FREI M S, CAPDEVILA-CORTADA M, GARCÍA-MUELAS R, et al. Mechanism and microkinetics of methanol synthesis via CO2 hydrogenation on indium oxide[J]. J Catal,2018,361:313−321. doi: 10.1016/j.jcat.2018.03.014
|
[19] |
CAO A, WANG Z, LI H, et al. Relations between surface oxygen vacancies and activity of methanol formation from CO2 hydrogenation over In2O3 surfaces[J]. ACS Catal,2021,11(3):1780−1786. doi: 10.1021/acscatal.0c05046
|
[20] |
GHOSH S, SEBASTIAN J, OLSSON L, et al. Experimental and kinetic modeling studies of methanol synthesis from CO2 hydrogenation using In2O3 catalyst[J]. Chem Eng J,2021,416:129120. doi: 10.1016/j.cej.2021.129120
|
[21] |
WANG Y, WANG G, VAN DER WAL L I, et al. Visualizing element migration over bifunctional metal-zeolite catalysts and its impact on catalysis[J]. Angew Chem Int Ed,2021,133(32):17876−17884. doi: 10.1002/ange.202107264
|
[22] |
RUI N, WANG Z, SUN K, et al. CO2 hydrogenation to methanol over Pd/In2O3: Effects of Pd and oxygen vacancy[J]. Appl Catal B: Environ,2017,218:488−497.
|
[23] |
SHEN C, SUN K, ZHANG Z, et al. Highly active Ir/In2O3 catalysts for selective hydrogenation of CO2 to methanol: experimental and theoretical studies[J]. ACS Catal,2021,11(7):4036−4046. doi: 10.1021/acscatal.0c05628
|
[24] |
ZHU J, CANNIZZARO F, LIU L, et al. Ni-In synergy in CO2 hydrogenation to methanol[J]. ACS Catal,2021,11(18):11371−11384. doi: 10.1021/acscatal.1c03170
|
[25] |
LIU T, HONG X, LIU G. In Situ generation of the Cu@ 3D-ZrO x framework catalyst for selective methanol synthesis from CO2/H2[J]. ACS Catal,2019,10(1):93−102.
|
[26] |
LIU T, XU D, SONG M, et al. K-ZrO2 interfaces boost CO2 hydrogenation to higher alcohols[J]. ACS Catal,2023,13(7):4667−4674. doi: 10.1021/acscatal.3c00074
|
[27] |
WEI W, WEI Z, LI R, et al. Subsurface oxygen defects electronically interacting with active sites on In2O3 for enhanced photothermocatalytic CO2 reduction[J]. Nat Commun,2022,13:3199. doi: 10.1038/s41467-022-30958-5
|
[28] |
FREI M S, MONDELLI C, GARCÍA-MUELAS R, et al. Nanostructure of nickel-promoted indium oxide catalysts drives selectivity in CO2 hydrogenation[J]. Nat Commun,2021,12(1):1960. doi: 10.1038/s41467-021-22224-x
|
[29] |
CHRISTOPHER N C, BRADY J C, HSIANG W C, et al. Aerogel synthesis of yttria-stabilized zirconia by a non-alkoxide sol-gel route[J]. Chem Mater,2005,17:3345−3351. doi: 10.1021/cm0503679
|
[30] |
XU D, HONG X, LIU G. Highly dispersed metal doping to ZnZr oxide catalyst for CO2 hydrogenation to methanol: Insight into hydrogen spillover[J]. J Catal,2021,393:207−214. doi: 10.1016/j.jcat.2020.11.039
|
[31] |
FENG Z, TANG C, ZHANG P, et al. Asymmetric sites on the ZnZrO x catalyst for promoting formate formation and transformation in CO2 hydrogenation[J]. J Am Chem Soc,2023,145:12663−12672.
|
[32] |
LI Z, MARTÍNEZ-TRIGUERO J, CONCEPCIÓN P, et al. Methanol to olefins: activity and stability of nanosized SAPO-34 molecular sieves and control of selectivity by silicon distribution[J]. Phys Chem Chem Phys,2013,15(35):14670−14680. doi: 10.1039/c3cp52247d
|
[33] |
SUN Q, WANG N, GUO G, et al. Ultrafast synthesis of nano-sized zeolite SAPO-34 with excellent MTO catalytic performance[J]. Chem Commun,2015,51(91):16397−16400. doi: 10.1039/C5CC07343J
|