[1] |
MANZER L E. Toward catalysis in the 21st century chemical industry[J]. Catalysis Today, 1993,18(2): 199-207.
|
[2] |
SCHMIDT F. The importance of catalysis in the chemical and non-chemical industries[J]. Basic Principles in Applied Catalysis, 2004, 35(17): 3-16.
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[3] |
GIDDEY S, BADWAL S. Review of electrochemical ammonia production technologies and materials[J]. International Journal of Hydrogen Energy, 2013,38(34):14576-14594.
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[4] |
YARULINA I, CHOWDURY A D, GASCON J, et al. Recent trends and fundamental insights in the methanol-to-hydrocarbons process[J]. Nature Catalysis, 2018,1(6): 398-411.
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[5] |
OLSBYE U, SVELLE S, BJORGEN M, et al. Conversion of methanol to hydrocarbons:How zeolite cavity and pore size controls product selectivity[J]. Angewandte Chemie-International Edition, 2012, 51(24): 5810-5831.
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[6] |
AIL S S, DASAPPA S. Biomass to liquid transportation fuel via Fischer Tropsch synthesis: Technology review and current scenario[J]. Renewable & Sustainable Energy Reviews, 2016,58: 267-286.
|
[7] |
ZHONG L S, YU F, AN Y L, et al. Cobalt carbide nanoprisms for direct production of lower olefins from syngas[J]. Nature, 2016, 538(7623): 84-87.
|
[8] |
WEI J, GE Q J, SUN J, et al. Directly converting CO2 into a gasoline fuel[J]. Nature Communications, 2017, 8: Article number 15147.
|
[9] |
JIAO F, LI J J, PAN X L, et al. Selective conversion of syngas to light olefins[J]. Science, 2016, 351(6277): 1065-1068.
|
[10] |
HOU Y H, HAN W C, XIA W S, et al. Structure sensitivity of La2O2CO3 catalysts in the oxidative coupling of methane[J]. ACS Catalysis, 2015, 5(3): 1663-1674.
|
[11] |
OTSUKA K, JINNO K, MORIKAWA A, et al. Active and selective catalysts for the synthesis of C2H4 and C2H6 via oxidative coupling of methane[J]. Journal of Catalysis, 1986,100(2): 353-359.
|
[12] |
NGUYEN T N, NHAT T P, TAKIMOTO K, et al. High-throughput experimentation and catalyst informatics for oxidative coupling of methane[J]. ACS Catalysis, 2019,10: 921-932.
|
[13] |
WEN W, YU S S, PAN Y, et al. Formation and fate of formaldehyde in methanol-to-hydrocarbon reaction: In situ synchrotron radiation photoionization mass spectrometry study[J]. Angewandte Chemie, 2020,132(12): 4903-4908.
|
[14] |
ZHOU Z Y, DU X W, QI F, et al. The vacuum ultraviolet beamline/endstations at NSRL dedicated to combustion research[J]. Journal of Synchrotron Radiation, 2016, 23(4):1035-1045.
|
[15] |
CHEUNG P, BHAN A, IGLESIA E, et al. Selective carbonylation of dimethyl ether to methyl acetate catalyzed by acidic zeolites[J]. Angew Chem Int Ed Engl, 2006,45(10):1617-1620.
|
[16] |
HE T, REN P G, LIU X C, et al. Direct observation of DME carbonylation in the different channels of H-MOR zeolite by continuous-flow solid-state NMR spectroscopy[J]. Chemical Communications, 2015,51(94):16868-16870.
|
[17] |
LIU J L, XUE H F, SHEN W J, et al. Dimethyl ether carbonylation to methyl acetate over HZSM-35[J]. Catalysis Letters, 2010,139(1-2): 33-37.
|
[18] |
XUE H, HUANG X Y, SHEN W J, et al. Selective dealumination of mordenite for enhancing its stability in dimethyl ether carbonylation[J]. Catalysis Communications, 2013, 37: 75-79.
|
[19] |
BORONAT M, MARTINEZ C, CORMA A. Mechanistic differences between methanol and dimethyl ether carbonylation in side pockets and large channels of mordenite[J]. Physical Chemistry Chemical Physics, 2011,13(7): 2603-2612.
|
[20] |
CHEUNG P, BHAN A, IGLESIA E, et al. Site requirements and elementary steps in dimethyl ether carbonylation catalyzed by acidic zeolites[J]. Journal of Catalysis, 2007, 245(1): 110-123.
|
[21] |
董大勤,袁凤隐. 压力容器设计手册[M].北京:化学工业出版社,2005:191.
|
[22] |
达道安. 真空设计手册[M].第3版.北京:国防工业出版社,2004:102-103.
|
[23] |
JOUSTEN K. Handbook of Vacuum Technology[M]. Weinheim, Germany: Wiley-VCH, 2016.
|
[24] |
HE X, FENG X , ZHONG M, et al. The influence of Laval nozzle throat size on supersonic molecular beam injection[J]. Journal of Modern Transportation, 2014, 22: 118-121.
|
[25] |
GASSER I, RYBICKI M. Modelling and simulation of gas dynamics in an exhaust pipe[J]. Applied Mathematical Modelling, 2013, 37(5): 2747-2764.
|
[26] |
WANG L P , QIU A C , KUAI B , et al. Study of the gas-puff line mass and density from Laval nozzle[J]. High Power Laser & Particle Beams, 2005, 17(2): 295-298.
|
[27] |
HE T, LIU X C, BAO X H, et al. Role of 12-ring channels of mordenite in DME carbonylation investigated by solid-state NMR[J]. Journal of Physical Chemistry C, 2016,120(39): 22526-22531.
|
[28] |
HUANG S Y, LI Y, MAX B, et al. Enhanced activity of Ce-incorporated MOR in DME carbonylation through tailoring the distribution of Bronsted acid[C]// 253rd ACS National Meeting & Exposition. Washington DC: American Chemical Society, 2017.
|
[29] |
XUE H F, HUANG X M, SHEN W J, et al. Dimethyl ether carbonylation to methyl acetate over nanosized mordenites[J]. Industrial & Engineering Chemistry Research, 2013, 52(33): 11510-11515.)
|
[1] |
MANZER L E. Toward catalysis in the 21st century chemical industry[J]. Catalysis Today, 1993,18(2): 199-207.
|
[2] |
SCHMIDT F. The importance of catalysis in the chemical and non-chemical industries[J]. Basic Principles in Applied Catalysis, 2004, 35(17): 3-16.
|
[3] |
GIDDEY S, BADWAL S. Review of electrochemical ammonia production technologies and materials[J]. International Journal of Hydrogen Energy, 2013,38(34):14576-14594.
|
[4] |
YARULINA I, CHOWDURY A D, GASCON J, et al. Recent trends and fundamental insights in the methanol-to-hydrocarbons process[J]. Nature Catalysis, 2018,1(6): 398-411.
|
[5] |
OLSBYE U, SVELLE S, BJORGEN M, et al. Conversion of methanol to hydrocarbons:How zeolite cavity and pore size controls product selectivity[J]. Angewandte Chemie-International Edition, 2012, 51(24): 5810-5831.
|
[6] |
AIL S S, DASAPPA S. Biomass to liquid transportation fuel via Fischer Tropsch synthesis: Technology review and current scenario[J]. Renewable & Sustainable Energy Reviews, 2016,58: 267-286.
|
[7] |
ZHONG L S, YU F, AN Y L, et al. Cobalt carbide nanoprisms for direct production of lower olefins from syngas[J]. Nature, 2016, 538(7623): 84-87.
|
[8] |
WEI J, GE Q J, SUN J, et al. Directly converting CO2 into a gasoline fuel[J]. Nature Communications, 2017, 8: Article number 15147.
|
[9] |
JIAO F, LI J J, PAN X L, et al. Selective conversion of syngas to light olefins[J]. Science, 2016, 351(6277): 1065-1068.
|
[10] |
HOU Y H, HAN W C, XIA W S, et al. Structure sensitivity of La2O2CO3 catalysts in the oxidative coupling of methane[J]. ACS Catalysis, 2015, 5(3): 1663-1674.
|
[11] |
OTSUKA K, JINNO K, MORIKAWA A, et al. Active and selective catalysts for the synthesis of C2H4 and C2H6 via oxidative coupling of methane[J]. Journal of Catalysis, 1986,100(2): 353-359.
|
[12] |
NGUYEN T N, NHAT T P, TAKIMOTO K, et al. High-throughput experimentation and catalyst informatics for oxidative coupling of methane[J]. ACS Catalysis, 2019,10: 921-932.
|
[13] |
WEN W, YU S S, PAN Y, et al. Formation and fate of formaldehyde in methanol-to-hydrocarbon reaction: In situ synchrotron radiation photoionization mass spectrometry study[J]. Angewandte Chemie, 2020,132(12): 4903-4908.
|
[14] |
ZHOU Z Y, DU X W, QI F, et al. The vacuum ultraviolet beamline/endstations at NSRL dedicated to combustion research[J]. Journal of Synchrotron Radiation, 2016, 23(4):1035-1045.
|
[15] |
CHEUNG P, BHAN A, IGLESIA E, et al. Selective carbonylation of dimethyl ether to methyl acetate catalyzed by acidic zeolites[J]. Angew Chem Int Ed Engl, 2006,45(10):1617-1620.
|
[16] |
HE T, REN P G, LIU X C, et al. Direct observation of DME carbonylation in the different channels of H-MOR zeolite by continuous-flow solid-state NMR spectroscopy[J]. Chemical Communications, 2015,51(94):16868-16870.
|
[17] |
LIU J L, XUE H F, SHEN W J, et al. Dimethyl ether carbonylation to methyl acetate over HZSM-35[J]. Catalysis Letters, 2010,139(1-2): 33-37.
|
[18] |
XUE H, HUANG X Y, SHEN W J, et al. Selective dealumination of mordenite for enhancing its stability in dimethyl ether carbonylation[J]. Catalysis Communications, 2013, 37: 75-79.
|
[19] |
BORONAT M, MARTINEZ C, CORMA A. Mechanistic differences between methanol and dimethyl ether carbonylation in side pockets and large channels of mordenite[J]. Physical Chemistry Chemical Physics, 2011,13(7): 2603-2612.
|
[20] |
CHEUNG P, BHAN A, IGLESIA E, et al. Site requirements and elementary steps in dimethyl ether carbonylation catalyzed by acidic zeolites[J]. Journal of Catalysis, 2007, 245(1): 110-123.
|
[21] |
董大勤,袁凤隐. 压力容器设计手册[M].北京:化学工业出版社,2005:191.
|
[22] |
达道安. 真空设计手册[M].第3版.北京:国防工业出版社,2004:102-103.
|
[23] |
JOUSTEN K. Handbook of Vacuum Technology[M]. Weinheim, Germany: Wiley-VCH, 2016.
|
[24] |
HE X, FENG X , ZHONG M, et al. The influence of Laval nozzle throat size on supersonic molecular beam injection[J]. Journal of Modern Transportation, 2014, 22: 118-121.
|
[25] |
GASSER I, RYBICKI M. Modelling and simulation of gas dynamics in an exhaust pipe[J]. Applied Mathematical Modelling, 2013, 37(5): 2747-2764.
|
[26] |
WANG L P , QIU A C , KUAI B , et al. Study of the gas-puff line mass and density from Laval nozzle[J]. High Power Laser & Particle Beams, 2005, 17(2): 295-298.
|
[27] |
HE T, LIU X C, BAO X H, et al. Role of 12-ring channels of mordenite in DME carbonylation investigated by solid-state NMR[J]. Journal of Physical Chemistry C, 2016,120(39): 22526-22531.
|
[28] |
HUANG S Y, LI Y, MAX B, et al. Enhanced activity of Ce-incorporated MOR in DME carbonylation through tailoring the distribution of Bronsted acid[C]// 253rd ACS National Meeting & Exposition. Washington DC: American Chemical Society, 2017.
|
[29] |
XUE H F, HUANG X M, SHEN W J, et al. Dimethyl ether carbonylation to methyl acetate over nanosized mordenites[J]. Industrial & Engineering Chemistry Research, 2013, 52(33): 11510-11515.)
|