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Chem. Int. Ed. 2022, 134: e202116990.0.1/a1b2 20Selective Removal of Acid Sites in Mordenite Zeolite by Trimethylchlorosilane Silylation to Improve Dimethyl Ether Carbonylation Stability, ACS Catal. 2022, 12: 4491-4500.02 30Dynamic Evolution of Aluminum Coordination Environments in Mordenite Zeolite and Their Role in the Dimethyl Ether (DME) Carbonylation Reaction, Angew. Chem. Int. Ed. 2022, 61: e202210658.028 40Ny9e'`NIQlwRP[[{SvQ6RYel N)RS: ZL 2019 1 0778904.X 2019t^08g22e/-,/-21322435273< 50NyV/lSEx Tvfnbc9e'`RP[[{v6RYel N)RS: ZL 2019 1 0778410.1 2019t^08g22e/-0/1253628392;3 R3z 10Direct Preparation of *MRE Zeolites with Ultralarge Mesoporosity: Strategy and Working Mechanism, ACS Applied Materials & Interfaces, 2021, 13(27): 31756-31765.c h- 20 Inter-zeolite transformation from *MRE to EUO: A new synthesis route for EUO zeolite,Catalysis Today, Catalysis Today, 2022, 405-406: 321-328.h i- 30Ny*MRE RP[[{SvQ6RYelT^(u N)R3uS: 202111185953.6, 2021t^10g12e0 0r3w232323 40NyZSM-48 RP[[{SvQ6RYelT^(u N)R3uS: 202210250755.1, 2022t^03g15e0 0r3w232323 50NyY~T[MRE RP[[{v6RYel N)R3uS: 202110269843.1, 2021t^03g12e0 0v3{232323 wsOsO~ 10Introducing Co-O moiety to Co-N-C single-atom catalyst for ethylbenzene dehydrogenation, ACS Catalysis, 2022, 12: 7760-7772.[-q 20Potassium-promoted single-atom Co-N-C catalyst for direct dehydrogenation of ethylbenzene, Nano Research, 2022.]-c6e qQ TN\O= 30USRcex}^5ё^\Pge\O:NYNe'l1"lPSBRv^(u N)R3uS202011101212.0, 2020t^10g15e/"-6/7-9/:-</ Y[=N 10High-Efficiency Water Gas Shift Reaction Catalysis on -MoC Promoted by Single-Atom Ir Species, ACS Catalysis, 2021, 11(10): 5942-5950.b- 20-MoC Supported Noble Metal Catalysts for Water Gas Shift Reaction: Single-Atom Promoter or Single-Atom Player, The Journal of Physical Chemistry Letters, 2021, 12(46): 11415-1< 1421.4r- 30Ru1/FeOx single-atom catalyst with dual active sites for water gas shift reaction without methanation, Applied Catalysis B Environmental, 2022, 318: 121841. 4. . i-7 40Ny'lSb}vWPSBRSvQ6RYT^(u N)R3uS202111498845.4 2021t^12g09e/-+/,-0/1-3/4-6/ spg 10Near 100% ethene selectivity achieved by tailoring dual active sites to isolate dehydrogenation and oxidation, Nature Communications, 2021, 12: 5447. q- 20 Main-group catalysts with atomically dispersed In sites for highly efficient oxidative dehydrogenation, Journal of the American Chemical Society, 2022, 144: 16855-16865.k-n 30NywQ gd[z1"lT'lSS;m'`MOpvPSBRSvQ6RYT^(u N)R3uS: 202110110249.8, 2021t^01g27eL/Q-g/h-j/k-m/y 40Q1_Ǐ^'lSTX:_C-H.;mSvPSBRS6RYT^(u N)R3uS: 202110110189.X, 2021t^01g27e W/\-r/s-u/v-x/ s7u 10Molecular elucidating of an unusual growth mechanism for polycyclic aromatic hydrocarbons in confined space, Nat. Commun., 2020, 11: 1079. o-|}- 20Coking and decoking chemistry for resource utilization of polycyclic aromatic hydrocarbons (PAHs) and low-carbon process, J. Energy Chem., 2022, 76: 105-116.|-A 30Ny)R(uRP[[{PSBR6RYUf{|STirvel N)RSZL 2019 1 0264943. 8,3ue2019t^04g03e0321362:3;2=3>2@3> 40Ny1u^srpp6RYUfSTirvel N)RSZL 2019 1 0264948. 0,3ue2019t^04g03e032.3327382:3;2=39 50NyUf{|STirv6RYel N)RSZL 2019 1 0264935. 3,3ue2019t^04g03e032)3.22332536283 s^e 10Acceleration effect of sodium halide on zeolite crystallization: ZSM-12 as a case study, Microporous and Mesoporous Materials, 2022, 331: 111652.[- 20 enBR_TbZSM-12RP[[{ S]ۏU\, 2022. /--Ne8h_7 30NyY~T[MTWWRP[[{vTbel N)R3uS: 201811416666.X, 2018t^11g26e  7 40NyNOExݔkMTWWRP[[{Tbel N)R3uS: 201811431268.5, 2018t^11g26e  /-//0-2/3-5/65 50NyMTWWRP[[{vTbel N)R3uS: 201911267058.1, 2019t^12g11e00v3{232323 60NyMTWWRP[[{vTbel N)R3uS: 201811415539.8, 2018t^11g26e00x3}232323 70NyMTWWRP[[{vVvTbel N)R3uS: 201911268372.1, 2019t^12g11e00o3t2323237 80NyNOExݔkBetaRP[[{vTbel N)R3uS: 201811460250.8, 2018t^11g30e0 03203123342636 90NyNOExݔkMFIWRP[[{Tbel N)R3uS: 201811460254.6, 2018t^11g30e0 032/302233253 sN~ 10Defect-Dependent Selective C H/C C Bond Cleavage of Propane in the Presence of CO2 over FeNi/Ceria Catalysts, ACS Sustainable Chem. Eng., 2021, 9: 17301-17309.T.Uq- 20Revealing the Catalytic Role of Sn Dopant in CO2-Oxidative Dehydrogenation of Propane over Pt/Sn-CeO2 Catalyst, ChemCatChem, 2022. 1.2f.gq-9 30NyNp'lS1"l6RNpvelS@b(uPSBR N)R3uS: 202111106726.X, 2021t^09g22e0322332536283 hgg0 ZSX0 10Highly Effective Pd/MgO/-Al2O3 Catalysts for CO Oxidative Coupling to Dimethyl Oxalate: The Effect of MgO Coating on -Al2O3, ACS Applied Materials & Interfaces, 2021, 13, 24: 28064-28071.01 1!|1}~12. 20txlTbؚkhbyv-Al2O3(WCO'lSvPTS^-Nv^(u, ]NPS,2022. 0 1100!#3'2 -Ne8h_6 30NyPd/MgO-Al2O3PSBR0vQ6RYelSvQ^(u N)R3uS: 201811458857.2, 2018t^11g30e0 110w3|232323 40NyPd/CaO-Al2O3PSBR0vQ6RYelSvQ^(u N)R3uS: 201811458845.X, 2018t^11g30e0 110t3y2323233 50NyPSBRv6RYelSvQ^(u N)R3uS: 202011458257.3, 2020t^12g10e032,3-2/302234 60NyPSBRSvQ6RYelTvQ^(u N)R3uS: 202011458281.7, 2020t^12g10e032-3.2031233  _` 10Synergy between Ru and WOx enables efficient hydrodeoxygenation of primary amides to amines, ACS Catalysis, 2022, 12: 6302-6312. ._- 20 Highly Chemoselective Reduction of Amides to Amines over a Ruthenium-Molybdenum Bimetallic Catalyst, ChemistrySelect, 2022, 7: e202203030.h- 30Ny^5ё^\PSBR(WpR"l1'l-Nv^(u < N)R3uS: 202211222923.2, 2022t^10g08e0p3 ,{NSfN([^,{N)66  \(A   =%  dMbP?_*+% &~?'~?(\.?)\.?" dXX BP(? 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