Tổng quan về các phản ứng hỗ trợ bởi plasma và ứng dụng tiềm năng trong việc sửa đổi khung hữu cơ kim loại

Mott-Smith H M. History of “plasmas”. Nature, 1971, 233(5316): 219–219 Jiang B, Zheng J T, Qiu S, Wu M B, Zhang Q H, Yan Z F, Xue Q Z. Review on electrical discharge plasma technology for wastewater remediation. Chemical Engineering Journal, 2014, 236: 348–368 Hinokuma S, Misumi S, Yoshida H, Machida M. Nanoparticle catalyst preparation using pulsed arc plasma deposition. Catalysis Science & Technology, 2015, 5(9): 4249–4257 Samukawa S, Hori M, Rauf S, Tachibana K, Bruggeman P, Kreesen G, Whitehead I C, Murphy A B, Gutsol A F, Starikovskaia S. The 2012 plasma roadmap. Journal of Physics. D, Applied Physics, 2012, 45(25): 253001 Kim S H, Moon S Y, Park J Y. Non-colloidal nanocatalysts fabricated using arc plasma deposition and their application in heterogenous catalysis and photocatalysis. Topics in Catalysis, 2017, 60(12): 812–822 Liu C J, Vissokov G P, Jang B W L. Catalyst preparation using plasma technologies. Catalysis Today, 2002, 72(3-4): 173–184 Wang Z Y, Liu C J. Preparation and application of iron oxide/graphene based composites for electrochemical energy storage and energy conversion devices: Current status and perspective. Nano Energy, 2015, 11: 277–293 Liu C J, Li M Y, Wang J Q, Zhou X T, Guo Q T, Yan J M, Li Y Z. Plasma methods for preparing green catalysts: Current status and perspective. Chinese Journal of Catalysis, 2016, 37(3): 340–348 Li H Q, Zou J J, Liu C J. Progress in hydrogen generation using plasmas. Progress in Chemistry, 2005, 17(1): 69–77 Bian L, Zhang L, Xia R, Li Z H. Enhanced low-temperature CO2 methanation activity on plasma-prepared Ni-based catalyst. Journal of Natural Gas Science and Engineering, 2015, 27: 1189–1194 Fu T J, Huang C D, Lv J, Li Z H. Fischer-Tropsch performance of an SiO2-supported Co-based catalyst prepared by hydrogen dielectric-barrier discharge plasma. Plasma Science & Technology, 2014, 16(3): 232–238 Park S, Choe W, Moon S Y, Yoo S J. Electron characterization in weakly ionized collisional plasmas: From principles to techniques. Advances in Physics-X, 2018, 4(1): 1526114 Ouyang J, Li B, He F, Dai D. Nonlinear phenomena in dielectric barrier discharges: Pattern, striation and chaos. Plasma Science & Technology, 2018, 20(10): 103002 Borra J P. Review on water electro-sprays and applications of charged drops with focus on the corona-assisted cone-jet mode for high efficiency air filtration by wet electro-scrubbing of aerosols. Journal of Aerosol Science, 2018, 125: 208–236 Yi H H, Zhao S Z, Tang X L, Song C Y, Gao F Y, Zhang B W, Wang Z X, Zuo Y R. Low-temperature hydrolysis of carbon disulfide using the Fe-Cu/AC catalyst modified by non-thermal plasma. Fuel, 2014, 128: 268–273 Naseh M V, Khodadadi A A, Mortazavi Y, Pourfayaz F, Alizadeh O, Maghrebi M. Fast and clean functionalization of carbon nanotubes by dielectric barrier discharge plasma in air compared to acid treatment. Carbon, 2010, 48(5): 1369–1379 Chen Q, Kaneko T, Hatakeyama R. Rapid synthesis of watersoluble gold nanoparticles with control of size and assembly using gas-liquid interfacial discharge plasma. Chemical Physics Letters, 2012, 521: 113–117 Zhou C M, Chen H, Yan Y B, Jia X L, Liu C J, Yang Y H. Argon plasma reduced Pt nanocatalysts supported on carbon nanotube for aqueous phase benzyl alcohol oxidation. Catalysis Today, 2013, 211: 104–108 Liu C J, Zhao Y, Li Y Z, Zhang D S, Chang Z, Bu X H. Perspectives on electron-assisted reduction for preparation of highly dispersed noble metal catalysts. ACS Sustainable Chemistry & Engineering, 2014, 2(1): 3–13 Ohkubo Y, Hamaguchi Y, Seino S, Nakagawa T, Kageyama S, Kugai J, Nitani H, Ueno K, Yamamoto T A. Preparation of carbon-supported PtCo nanoparticle catalysts for the oxygen reduction reaction in polymer electrolyte fuel cells by an electron-beam irradiation reduction method. Journal of Materials Science, 2013, 48(14): 5047–5054 Pastor-Perez L, Belda-Alcazar V, Marini C, Pastor-Blas M M, Sepulveda-Escribana A, Ramos-Fernandez E V. Effect of cold Ar plasma treatment on the catalytic performance of Pt/CeO2 in watergas shift reaction (WGS). Applied Catalysis B: Environmental, 2018, 225: 121–127 Liu C, Lan J P, Sun F L, Zhang Y H, Li J L, Hong J P. Promotion effects of plasma treatment on silica supports and catalyst precursors for cobalt Fischer-Tropsch catalysts. RSC Advances, 2016, 6(62): S7701–S7708 Neyts E C, Ostrikov K, Sunkara M K, Bogaerts A. Plasma catalysis: Synergistic effects at the nanoscale. Chemical Reviews, 2015, 115(24): 13408–13446 Wang Z, Zhang Y, Neyts E C, Cao X X, Zhang X S, Jang B W L, Liu C J. Catalyst preparation with plasmas: How does it work? ACS Catalysis, 2018, 8(3): 2093–2110 Sadakiyo M, Heima M, Yamamoto T, Matsumura S, Matsuura M, Sugimoto S, Kato K, Takata M, Yamauchi M. Preparation of solid-solution type Fe-Co nanoalloys by synchronous deposition of Fe and Co using dual arc plasma guns. Dalton Transactions (Cambridge, England), 2015, 44(36): 15764–15768 Rosi N L, Kim J, Eddaoudi M, Chen B L, O’Keeffe M, Yaghi O M. Rod packings and metal-organic frameworks constructed from rodshaped secondary building units. Journal of the American Chemical Society, 2005, 127(5): 1504–1518 Gilman A B, Piskarev M S, Kuznetsov A A, Ozerin A N. Modification of ultrahigh-molecular-weight polyethylene by low-temperature plasma. High Energy Chemistry, 2017, 51(2): 136–144 Sun Y P, Nie Y, Yuan J, Wu A S, Shen J L, Ji D X, Yu F W, Ji J B. Application of plasma technology in the reaction of methane carbon dioxide reforming to syngas. Chemical Industry and Engineering Progress, 2010, 29(S1): 295–300 Chung W C, Chang M B. Review of catalysis and plasma performance on dry reforming of CH4 and possible synergistic effects. Renewable & Sustainable Energy Reviews, 2016, 62: 13–31 Zhou T, Jang K, Jang B W L. Ionic liquid and plasma effects on SiO2 supported Pd for selective hydrogenation of acetylene. Catalysis Today, 2013, 211: 147–155 Zhou C M, Wang X, Jia X L, Wang H P, Liu C J, Yang Y H. Nanoporous platinum grown on nickel foam by facile plasma reduction with enhanced electro-catalytic performance. Electrochemistry Communications, 2012, 18: 33–36 Platonov E A, Bratchikova I G, Yagodovskii V D, Murga Z V. Carbon dioxide reforming of methane on a cobalt catalyst subjected to plasma-chemical treatment. Russian Journal of Physical Chemistry A, 2017, 91(8): 1422–1426 Wu Y W, Chung W C, Chang M B. Modification of Ni/gamma-Al2O3 catalyst with plasma for steam reforming of ethanol to generate hydrogen. International Journal of Hydrogen Energy, 2015, 40(25): 8071–8080 Zhu B, Jang BWL. Insights into surface properties of non-thermal RF plasmas treated Pd/TiO2 in acetylene hydrogenation. Journal of Molecular Catalysis A Chemical, 2014, 395: 137–144 Movasati A, Alavi S M, Mazloom G. Dry reforming of methane over CeO2-ZnAl2O4 supported Ni and Ni-Co nano-catalysts. Fuel, 2019, 236: 1254–1262 Song K, Lu M, Xu S, Chen C, Zhan Y, Li D, Au C, Jiang L, Tomishige K. Effect of alloy composition on catalytic performance and coke-resistance property of Ni-Cu/Mg(Al)O catalysts for dry reforming of methane. Applied Catalysis B: Environmental, 2018, 239: 324–333 Li Z, Das S, Hongmanorom P, Dewangan N, Wai M H, Kawi S. Silica-based micro- and mesoporous catalysts for dry reforming of methane. Catalysis Science & Technology, 2018, 8(11): 2763–2778 Tu X, Whitehead J C. Plasma dry reforming of methane in an atmospheric pressure AC gliding arc discharge: Co-generation of syngas and carbon nanomaterials. International Journal of Hydrogen Energy, 2014, 39(18): 9658–9669 Lim M S, Chun Y N. Carbon dioxide destruction with methane reforming by a novel plasma-catalytic converter. Plasma Chemistry and Plasma Processing, 2016, 36(5): 1211–1228 Li X S, Zhu B, Shi C, Xu Y, Zhu A M. Carbon dioxide reforming of methane in kilohertz spark-discharge plasma at atmospheric pressure. AIChE Journal. American Institute of Chemical Engineers, 2011, 57(10): 2854–2860 Zhou Z P, Zhang J M, Ye T H, Zhao P H, Xia W D. Hydrogen production by reforming methane in a corona inducing dielectric barrier discharge and catalyst hybrid reactor. Chinese Science Bulletin, 2011, 56(20): 2162–2166 Li X, Tao X M, Yin Y X. An atmospheric-pressure glow-discharge plasma jet and its application. IEEE Transactions on Plasma Science, 2009, 37(6): 759–763 Jo S, Lee D H, Song Y H. Product analysis of methane activation using noble gases in a non-thermal plasma. Chemical Engineering Science, 2015, 130: 101–108 Park S, Lee M, Bae J, Hong D Y, Park Y K, Hwang Y K, Jeong M G, Kim Y D. Plasma-assisted non-oxidative conversion of methane over Mo/HZSM-5 catalyst in DBD reactor. Topics in Catalysis, 2017, 60(9-11): 735–742 Ray D, Reddy P M K, Challapalli S. Glass beads packed DBD-plasma assisted dry reforming of methane. Topics in Catalysis, 2017, 60(12-14): 869–878 Zhang K, Mukhriza T, Liu X T, Greco P P, Chiremba E. A study on CO2 and CH4 conversion to synthesis gas and higher hydrocarbons by the combination of catalysts and dielectric-barrier discharges. Applied Catalysis A, General, 2015, 502: 138–149 Zheng X G, Tan S Y, Dong L C, Li S B, Chen H M, Wei S A. Experimental and kinetic investigation of the plasma catalytic dry reforming of methane over perovskite LaNiO3 nanoparticles. Fuel Processing Technology, 2015, 137: 250–258 Chung W C, Tsao I Y, Chang M B. Novel plasma photocatalysis process for syngas generation via dry reforming of methane. Energy Conversion and Management, 2018, 164: 417–428 Xia Y, Lu N, Wang B, Li J, Shang K, Jiang N, Wu Y. Dry reforming of CO2-CH4 assisted by high-frequency AC gliding arc discharge: Electrical characteristics and the effects of different parameters. International Journal of Hydrogen Energy, 2017, 42 (36): 22776–22785 Montoro-Damas A M, Brey J J, Rodríguez MA, Gonzalez-Elipe A R, Cotrino J. Plasma reforming of methane in a tunable ferroelectric packed-bed dielectric barrier discharge reactor. Journal of Power Sources, 2015, 296: 268–275 Jin L J, Li Y, Feng Y Q, Hu H Q, Nu A M. Integrated process of coal pyrolysis with CO2 reforming of methane by spark discharge plasma. Journal of Analytical and Applied Pyrolysis, 2017, 126: 194–200 Mustafa M F, Fu X D, Lu W J, Liu Y J, Abbas Y, Wang H T, Arslan M T. Application of non-thermal plasma technology on fugitive methane destruction: Configuration and optimization of double dielectric barrier discharge reactor. Journal of Cleaner Production, 2018, 174: 670–677 Nguyen H H, Nasonova A, Nah I W, Kim K S. Analysis on CO2 reforming of CH4 by corona discharge process for various process variables. Journal of Industrial and Engineering Chemistry, 2015, 32: 58–62 Wang B W, Sun Q M, Lu Y J, Yang M L, Yan W J. Steam reforming of dimethyl ether by gliding arc gas discharge plasma for hydrogen production. Chinese Journal of Chemical Engineering, 2014, 22(1): 104–112 Iwarere S A, Rohani V J, Ramjugernath D, Fulcheri L. Dry reforming of methane in a tip-tip arc discharge reactor at very high pressure. International Journal of Hydrogen Energy, 2015, 40(8): 3388–3401 Xu G H, Jiang E Y, Sheng J. Technology and application of plasma. Beijing: Chemical Industry Press, 2006: 1–242 (in Chinese) Yap D, Tatibouet J M, Batiot-Dupeyrat C. Catalyst assisted by nonthermal plasma in dry reforming of methane at low temperature. Catalysis Today, 2018, 299: 263–271 Sentek J, Krawczyk K, Mlotek M, Kalczewska M, Kroker T, Kolb T, Schenk A, Gericke K H, Schmidt-Szalowski K. Plasma-catalytic methane conversion with carbon dioxide in dielectric barrier discharges. Applied Catalysis B: Environmental, 2010, 94(1-2): 19–26 Kim J, Abbott M S, Go D B, Hicks J C. Enhancing C–H bond activation of methane via temperature-controlled, catalyst-plasma interactions. ACS Energy Letters, 2016, 1(1): 94–99 Snoeckx R, Aerts R, Tu X, Bogaerts A. Plasma-based dry reforming: A computational study ranging from the nanoseconds to seconds time scale. Journal of Physical Chemistry C, 2013, 117 (10): 4957–4970 Kim H H, Teramoto Y, Negishi N, Ogata A. A multidisciplinary approach to understand the interactions of nonthermal plasma and catalyst: A review. Catalysis Today, 2015, 256: 13–22 Meinshausen M, Meinshausen N, Hare W, Raper S C B, Frieler K, Knutti R, Frame D J, Allen M R. Greenhouse-gas emission targets for limiting global warming to 2°C. Nature, 2009, 458(7242): 1158–1162 Matthews H D, Gillett N P, Stott P A, Zickfeld K. The proportionality of global warming to cumulative carbon emissions. Nature, 2009, 459(7248): 829–832 Wise M, Calvin K, Thomson A, Clarke L, Bond-Lamberty B, Sands R, Smith S J, Janetos A, Edmonds J. Implications of limiting CO2 concentrations for land use and energy. Science, 2009, 324 (5931): 1183–1186 Lu Y W, Yan Q G, Han J, Cao B B, Street J, Yu F. Fischer-Tropsch synthesis of olefin-rich liquid hydrocarbons from biomass-derived syngas over carbon-encapsulated iron carbide/iron nanoparticles catalyst. Fuel, 2017, 193: 369–384 Foit S R, Vinke I C, de Haart L G J, Eichel R A. Power-to-syngas: An enabling technology for the transition of the energy system? Angewandte Chemie International Edition, 2017, 56(20): 5402–5411 Wang L, Yi Y H, Guo H C, Tu X. Atmospheric pressure and room temperature synthesis of methanol through plasma-catalytic hydrogenation of CO2. ACS Catalysis, 2018, 8(1): 90–100 Saeidi S, Amin N A S, Rahimpour M R. Hydrogenation of CO2 to value-added products—A review and potential future developments. Journal of CO2 Utilization, 2014, 5: 66–81 Federsel C, Jackstell R, Beller M. State-of-the-art catalysts for hydrogenation of carbon dioxide. Angewandte Chemie International Edition, 2010, 49(36): 6254–6257 Dimitriou I, Garcia-Gutierrez P, Elder R H, Cuellar-France R M, Azapagic A, Allen R W K. Carbon dioxide utilisation for production of transport fuels: Process and economic analysis. Energy & Environmental Science, 2015, 8(6): 1775–1789 Omae I. Aspects of carbon dioxide utilization. Catalysis Today, 2006, 115(1): 33–52 Jessop P G, Ikariya T, Noyori R. Homogeneous catalytic-hydrogen of carbon dioxide. Nature, 1994, 368(6468): 231–233 Alexmills G, Steffgen F. Catalytic methanation. Catalysis Reviews, 1974, 8(1): 159–210 Paulussen S, Verheyde B, Tu X, De Bie C, Martens T, Petrovic D, Bogaerts A, Sels B. Conversion of carbon dioxide to value-added chemicals in atmospheric pressure dielectric barrier discharges. Plasma Sources Science & Technology, 2010, 19(3): 34015–34016 Pinhão N R, Janeco A, Branco J B. Influence of helium on the conversion of methane and carbon dioxide in a dielectric barrier discharge. Plasma Chemistry and Plasma Processing, 2011, 31(3): 427–439 Eliasson B, Kogelschatz U, Xue B Z, Zhou L M. Hydrogenation of carbon dioxide to methanol with a discharge-activated catalyst. Industrial & Engineering Chemistry Research, 1998, 37(8): 3350–3357 Gómez-Ramírez A, Rico V J, Cotrino J, Gonzalez-Elipe A, Lambert R M. Low temperature production of formaldehyde from carbon dioxide and ethane by plasma-assisted catalysis in a ferroelectrically moderated dielectric barrier discharge reactor. ACS Catalysis, 2014, 4(2): 402–408 Van Laer K, Bogaerts A. Improving the conversion and energy efficiency of carbon dioxide splitting in a zirconia-packed dielectric barrier discharge reactor. Energy Technology (Weinheim), 2015, 3(10): 1038–1044 Ramakers M, Michielsen I, Aerts R, Meynen V, Bogaerts A. Effect of argon or helium on the CO2 conversion in a dielectric barrier discharge. Plasma Processes and Polymers, 2015, 12(8): 755–763 van Rooij G J, van den Bekerom D C M, den Harder N, Minea T, Berden G, Bongers WA, Engeln R, Graswinckel M F, Zoethout E, de Sandena M C M V. Taming microwave plasma to beat thermodynamics in CO2 dissociation. Faraday Discussions, 2015, 183: 233–248 Bongers W, Bouwmeester H, Wolf B, Peeters F, Welzel S, van den Bekerom D, den Harder N, Goede A, Graswinckel M, Green P W, et al. Plasma-driven dissociation of CO2 for fuel synthesis. Plasma Processes and Polymers, 2017, 14(6): 1600126 Silva T, Britun N, Godfroid T, Snyders R. Optical characterization of a microwave pulsed discharge used for dissociation of CO2. Plasma Sources Science & Technology, 2014, 23(2): 217–221 Spencer L F, Gallimore A D. CO2 dissociation in an atmospheric pressure plasma/catalyst system: A study of efficiency. Plasma Sources Science & Technology, 2013, 22(1): 015019 Ramakers M, Trenchev G, Heijkers S, Wang W Z, Bogaerts A. Gliding arc plasmatron: Providing an alternative method for carbon dioxide conversion. ChemSusChem, 2017, 10(12): 2642–2652 Li K, Liu J L, Li X S, Zhu X B, Zhu A M. Warm plasma catalytic reforming of biogas in a heat-insulated reactor: Dramatic energy efficiency and catalyst auto-reduction. Chemical Engineering Journal, 2016, 288: 671–679 Liu J L, Park H W, Chung W J, Ahn W S, Park D W. Simulated biogas oxidative reforming in AC-pulsed gliding arc discharge. Chemical Engineering Journal, 2016, 285: 243–251 Liu J L, Park H W, Chung W J, Park D W. High-efficient conversion of CO2 in AC-pulsed tornado gliding arc plasma. Plasma Chemistry and Plasma Processing, 2016, 36(2): 437–449 Shapoval V, Marotta E, Ceretta C, Konjevic N, Ivkovic M, Schiorlin M, Paradisi C. Development and testing of a selftriggered spark reactor for plasma driven dry reforming of methane. Plasma Processes and Polymers, 2014, 11(8): 787–797 Zhu B, Li X S, Shi C, Liu J L, Zhao T L, Zhu A M. Pressurization effect on dry reforming of biogas in kilohertz spark-discharge plasma. International Journal of Hydrogen Energy, 2012, 37(6): 4945–4954 Zhu B, Li X S, Liu J L, Zhu X B, Zhu A M. Kinetics study on carbon dioxide reforming of methane in kilohertz spark-discharge plasma. Chemical Engineering Journal, 2015, 264: 445–452 Lee C J, Lee D H, Kim T. Enhancement of methanation of carbon dioxide using dielectric barrier discharge on a ruthenium catalyst at atmospheric conditions. Catalysis Today, 2017, 293: 97–104 Nizio M, Benrabbah R, Krzak M, Debek R, Motak M, Caavadias S, Galvez M E, Da Costa P. Low temperature hybrid plasmacatalytic methanation over Ni-Ce-Zr hydrotalcite-derived catalysts. Catalysis Communications, 2016, 83: 14–17 Nizio M, Albarazi A, Cavadias S, Amouroux J, Galvez M E, Da Costa P. Hybrid plasma-catalytic methanation of CO2 at low temperature over ceria zirconia supported Ni catalysts. International Journal of Hydrogen Energy, 2016, 41(27): 11584–11592 Zhang Y R, Van Laer K, Neyts E C, Bogaerts A. Can plasma be formed in catalyst pores? A modeling investigation. Applied Catalysis B: Environmental, 2016, 185: 56–67 Bruggeman P J, Kushner M J, Locke B R, Gardeniers J G E, Graham W G, Graves D B, Hofmann-Caris R C H M, Maric D, Reid J P, Ceriani E, et al. Plasma-liquid interactions: A review and roadmap. Plasma Sources Science & Technology, 2016, 25(5): 1–125 Bruggeman P J, Czarnetzki U. Retrospective on ‘The 2012 Plasma Roadmap’. Journal of Physics. D, Applied Physics, 2016, 49(43): 431001 Aziz M A A, Jalil A A, Triwahyono S, Mukti R R, Taufiq-Yap Y H, Sazegar M R. Highly active Ni-promoted mesostructured silica nanoparticles for CO2 methanation. Applied Catalysis B: Environmental, 2014, 147: 359–368 Ren J, Guo H L, Yang J Y, Qin Z F, Lin J Y, Li Z. Insights into the mechanisms of CO2 methanation on Ni(111) surfaces by density functional theory. Applied Surface Science, 2015, 351: 504–516 Weatherbee G D, Bartholomew C H. Hydrogenation of CO2 on group VIII metals. II. Kinetics and mechanism of CO2 hydrogenation on nickel. Journal of Catalysis, 1982, 77(2): 460–472 Upham D C, Derk A R, Sharma S, Metiu H, McFarland E W. CO2 methanation by Ru-doped ceria: The role of the oxidation state of the surface. Catalysis Science & Technology, 2015, 5(3): 1783–1791 Azzolina-Jury F, Bento D, Henriques C, Thibault-Starzyk F. Chemical engineering aspects of plasma-assisted CO2 hydrogenation over nickel zeolites under partial vacuum. Journal of CO2 Utilization, 2017, 22: 97–109 Jiang Q, Lin Q, Huang Z T. Study on carbon dioxide methanation catalyst III. Catalytic reaction mechanism under the action of Ni-Ru-rare earth/ZrO2. Journal of Catalysis, 1997, (3): 189–139 (in Chinese) Jwa E, Lee S B, Lee H W, Mok Y S. Plasma-assisted catalytic methanation of CO and CO2 over Ni-zeolite catalysts. Fuel Processing Technology, 2013, 108: 89–93 Speckmann F W, Mueller D, Koehler J, Birke K P. Low pressure glow-discharge methanation with an ancillary oxygen ion conductor. Journal of CO2 Utilization, 2017, 19: 130–136 Aerts R, Somers W, Bogaerts A. Carbon dioxide splitting in a dielectric barrier discharge plasma: A combined experimental and computational study. ChemSusChem, 2015, 8(4): 702–716 Azzolina-Jury F, Thibault-Starzyk F. Mechanism of low pressure plasma-assisted CO2 hydrogenation over Ni-USY by microsecond time-resolved FTIR spectroscopy. Topics in Catalysis, 2017, 60 (19): 1709–1721 Yan X L, Bao J H, Zhao B R, Yuan C, Hu T, Huang C F, Li Y N. CO dissociation on Ni/SiO2: The formation of different carbon materials. Topics in Catalysis, 2017, 60(12-14): 890–897 Dai B, Gong W M, Zhang X L, Zhang L, He R. Studies on methanation of CO2 under synergism plasma with catalyst. Chemical Journal of Chinese Universities, 2001, 22(5): 817–820 (in Chinese) Jing L, Li Z H. Conversion of natural gas to C hydrocarbons via cold plasma technology. Journal of Energy Chemistry, 2010, 19(4): 375–379 Xu D J, Li Z H, Lv J, Wang B W, Xu G H. Methane conversion to C2 and higher hydrocarbons via dielectric-barrier discharge plasma at atmospheric pressure. Chemical Reaction Engineering & Technology, 2006, 22(4): 356–360 Lee D H, Song Y H, Kim K T, Lee J O. Comparative study of methane activation process by different plasma sources. Plasma Chemistry and Plasma Processing, 2013, 33(4): 647–661 Zhang X L, Di L B, Zhou Q. Methane conversion under cold plasma over Pd-containing ionic liquids immobilized on gamma-Al2O3. Journal of Energy Chemistry, 2013, 22(3): 446–450 Wilkes J S. A short history of ionic liquids-from molten salts to neoteric solvents. Green Chemistry, 2002, 4(2): 73–80 Nozaki T, Hattori A, Okazaki K. Partial oxidation of methane using a microscale non-equilibrium plasma reactor. Catalysis Today, 2004, 98(4): 607–616 Wang D W, Ma T C. Catalytic methane coupling of C2 hydrocarbons by glow discharge plasma. Nuclear Fusion and Plasma Physics, 2006, 4: 327–330 (in Chinese) Goujard V, Tatibouët J M, Batiot-Dupeyrat C. Carbon dioxide reforming of methane using a dielectric barrier discharge reactor: Effect of helium dilution and kinetic model. Plasma Chemistry and Plasma Processing, 2011, 31(2): 315–325 Thanyachotpaiboon K, Chavadej S, Caldwell T A, Lobban L L, Mallinson R G. Conversion of methane to higher hydrocarbons in AC nonequilibrium plasmas. AIChE Journal. American Institute of Chemical Engineers, 1998, 44(10): 2252–2257 Zhang A J, Zhu A M, Guo J, Xu Y, Shi C. Conversion of greenhouse gases into syngas via combined effects of discharge activation and catalysis. Chemical Engineering Journal, 2010, 156 (3): 601–606 Jo S, Lee D H, Kang S, Song Y H. Methane activation using noble gases in a dielectric barrier discharge reactor. Physics of Plasmas, 2013, 20(8): 14–31 Jo S, Lee D H, Kim K T, Kang WS, Song Y H. Methane activation using Kr and Xe in a dielectric barrier discharge reactor. Physics of Plasmas, 2014, 21(10): 14–31 Sudnick J J, Corwin D L. VOC control techniques. Hazardous Waste & Hazardous Materials, 1994, 11(1): 129–143 Keller R A, Dyer J A. Abating halogenated VOCs. Chemical Engineering (Albany, N.Y.), 1998, 105(1): 100–105 Kim H H, Ogata A, Futamura S. Complete oxidation of volatile organic compounds (VOCs) using plasma-driven catalysis and oxygen plasma. International Journal of Plasma Environmental Science & Technology, 2007, 1: 46–51 Dyer J A, Mulholland K. Toxic air emissions. What is the full cost to your business? Chemical Engineering Environmental Engineering, 1994, 101 (S2):4–8 Okubo M, Yamamoto T, Kuroki T, Fukumoto H. Electric air cleaner composed of nonthermal plasma reactor and electrostatic precipitator. IEEE Transactions on Industry Applications, 2001, 37 (5): 1505–1511 Chang C L, Lin T S. Decomposition of toluene and acetone in packed dielectric barrier discharge reactors. Plasma Chemistry and Plasma Processing, 2005, 25(3): 227–243 Ohshima T, Kondo T, Kitajima N, Sato M. Adsorption and plasma decomposition of gaseous acetaldehyde on fibrous activated carbon. IEEE Transactions on Industry Applications, 2010, 46 (1): 23–28 Vandenbroucke A, Mora M, Morent R, De Geyter N, Leys C. TCE abatement with a plasma-catalysis combined system using MnO2 as catalyst. 21st International Symposium on Plasma Chemistry, 2013, 156: 94–100 Dinh M T N, Giraudon J M, Lamonier J F, Vandenbroucke A, De Geyter N, Leys C, Morent R. Plasma-catalysis of low TCE concentration in air using LaMnO3+δ as catalyst. Applied Catalysis B: Environmental, 2014, 147(147): 904–911 Assadi A A, Bouzaza A, Vallet C, Wolbert D. Use of DBD plasma,photocatalysis, and combined DBD plasma/photocatalysis in a continuous annular reactor for isovaleraldehyde elimination-Synergetic effect and byproducts identification. Chemical Engineering Journal, 2014, 254(13): 124–132 Ogata A, Ito D, Mizuno K, Kushiyama S, Gal A, Yamamoto T. Effect of coexisting components on aromatic decomposition in a packed-bed plasma reactor. Applied Catalysis A, General, 2002, 236(1): 9–15 Yamamoto T, Mizuno K, Tamori I, Ogata A, Nifuku M, Michalska M, Prieto G. Catalysis-assisted plasma technology for carbon tetrachloride destruction. IEEE Transactions on Industry Applications, 1996, 32(1): 100–105 Ogata A, Yamanouchi K, Mizuno K, Kushiyama S, Yamamoto T. Oxidation of dilute benzene in an alumina hybrid plasma reactor at atmospheric pressure. Plasma Chemistry and Plasma Processing, 1999, 19(3): 383–394 Ogata A, Ito D, Mizuno K, Kushiyamaet S, Yamamoto T. Removal of dilute benzene using a zeolite-hybrid plasma reactor. IEEE Transactions on Industry Applications, 2001, 37(4): 959–964 Oh S M, Kim H H, Einaga H, Ogata A, Futamura S, Park D W. Zeolite-combined plasma reactor for decomposition of toluene. Thin Solid Films, 2006, 506-507: 418–422 Kuroki T, Hirai K, Matsuoka S, Kim J Y, Okubo M. Oxidation system of adsorbed VOCs on adsorbent using nonthermal plasma flow. IEEE Transactions on Industry Applications, 2011, 47(4): 1916–1921 Feng F D, Zheng Y Y, Shen X J, Zheng Q Z, Dai S L, Zhang X M, Huang Y F, Liu Z, Yan K P. Characteristics of back corona discharge in a honeycomb catalyst and its application for treatment of volatile organic compounds. Environmental Science & Technology, 2015, 49(11): 6831–6837 Sultana S, Vandenbroucke A M, Leys C, De Geyter N, Morent R. Abatement of VOCs with alternate adsorption and plasma-assisted regeneration: A review. Catalysts, 2015, 5(2): 718–746 Schiavon M, Torretta V, Casazza A, Ragazzi M. Non-thermal plasma as an innovative option for the abatement of volatile organic compounds: A review. Water, Air, and Soil Pollution, 2017, 228(10): 388 Vandenbroucke A M, Morent R, De Geyter N, Leys C. Nonthermal plasmas for non-catalytic and catalytic VOC abatement. Journal of Hazardous Materials, 2011, 195: 30–54 Feng X X, Liu H X, He C, Shen Z X, Wang T B. Synergistic effects and mechanism of a non-thermal plasma catalysis system in volatile organic compound removal: A review. Catalysis Science & Technology, 2018, 8(4): 936–954 Yang F, Li Y F, Liu T, Xu K, Zhang L Q, Xu C M, Gao J S. Plasma synthesis of Pd nanoparticles decorated-carbon nanotubes and its application in Suzuki reaction. Chemical Engineering Journal, 2013, 226: 52–58 Liang H F, Gandi A N, Anjum D H,Wang X B, Schwingenschlogl U, Alshareef H N. Plasma-assisted synthesis of NiCoP for efficient overall water splitting. Nano Letters, 2016, 16(12): 7718–7725 Wang S Y, Wang X Y, Wang L, Pu Q S, Du W B, Guo G S. Plasma-assisted alignment in the fabrication of microchannelarray- based in-tube solid-phase microextraction microchips packed with TiO2 nanoparticles for phosphopeptide analysis. Analytica Chimica Acta, 2018, 1018: 70–77 Li S J, Li L L, Chen Z, Xue G P, Jiang L G, Zheng K, Chen J C, Li R, Yuan C, Huang M D. A novel purification procedure for recombinant human serum albumin expressed in Pichia pastoris. Protein Expression and Purification, 2018, 149: 37–42 Cong Z, Lee S. Study of mechanical behavior of BNNT-reinforced aluminum composites using molecular dynamics simulations. Composite Structures, 2018, 194: 80–86 Cogal S, Ela S E, Ali A K, Cogal G C, Micusik M, Omastova M, Oksuz A U. Polyfuran-based multi-walled carbon nanotubes and graphene nanocomposites as counter electrodes for dye-sensitized solar cells. Research on Chemical Intermediates, 2018, 44(5): 3325–3335 Qiu B, Yang C, Guo W H, Xu Y, Liang Z B, Ma D, Zou R Q. Highly dispersed Co-based Fischer-Tropsch synthesis catalysts from metal-organic frameworks. Journal of Materials Chemistry. A, Materials for Energy and Sustainability, 2017, 5(17): 8081–8086 Zhu L, Liu X Q, Jiang H L, Sun L B. Metal-organic frameworks for heterogeneous basic catalysis. Chemical Reviews, 2017, 117(12): 8129–8176 Jing P, Zhang S Y, Chen W J, Wang L, Shi W, Cheng P. A macroporous metal-organic framework with enhanced hydrophobicity for efficient oil adsorption. Chemistry-a European Journal, 2018, 24(15): 3754–3759 Carrasco J A, Romero J, Abellan G, Hernandez-Saz J, Molina S I, Marti-Gastaldo C, Coronado E. Small-pore driven high capacitance in a hierarchical carbon via carbonization of Ni-MOF-74 at low temperatures. Chemical Communications, 2016, 52(58): 9141–9144 Li Y Q, Gao Q, Zhang L J, Zhou Y S, Zhong Y X, Ying Y, Zhang M C, Huang C Q, Wang Y A. H5PV2Mo10O40 encapsulated in MIL-101(Cr): Facile synthesis and characterization of rationally designed composite materials for efficient decontamination of sulfur mustard. Dalton Transactions (Cambridge, England), 2018, 47(18): 6394–6403 Zhen W L, Li B, Lu G X, Ma J T. Enhancing catalytic activity and stability for CO2 methanation on Ni@MOF-5 via control of active species dispersion. Chemical Communications, 2015, 51(9): 1728–1731 Li Y J, Miao J P, Sun X J, Xiao J, Li Y W,Wang H H, Xia Q B, Li Z. Mechanochemical synthesis of Cu-BTC@GO with enhanced water stability and toluene adsorption capacity. Chemical Engineering Journal, 2016, 298: 191–197 Zeng L, Xiao L, Long Y K, Shi X W. Trichloroacetic acidmodulated synthesis of polyoxometalate@UiO-66 for selective adsorption of cationic dyes. Journal of Colloid and Interface Science, 2018, 516: 274–283 Sadakiyo M, Yoshimaru S, Kasai H, Kato K, Takata M, Yamauchi M. A new approach for the facile preparation of metal-organic framework composites directly contacting with metal nanoparticles through arc plasma deposition. Chemical Communications, 2016, 52(54): 8385–8388 Park K S, Ni Z, Côté A P, Choi J Y, Huang R D, Uribe-Romo F J, Chae H K, O’Keeffe M, Yaghi O M. Exceptional chemical and thermal stability of zeolitic imidazolate frameworks. Proceedings of the National Academy of Sciences of the United States of America, 2006, 103(27): 10186–10191 Férey G, Mellot-Draznieks C, Serre C, Millange F, Dutour J, Surble S, Margiolaki I. A chromium terephthalate-based solid with unusually large pore volumes and surface area. Science, 2005, 309 (5743): 2040–2042 Kandiah M, Usseglio S, Svelle S, Olsbye U, Lillerud K P, Tilset M. Post-synthetic modification of the metal-organic framework compound UiO-66. Journal of Materials Chemistry, 2010, 20 (44): 9848–9851 Fujitani T, Nakamura I, Akita T, Okumura M, Haruta M. Hydrogen dissociation by gold clusters. Angewandte Chemie, 2009, 121(50): 9679–9682 Bahri M, Haghighat F, Rohani S, Kazemian H. Metal organic frameworks for gas-phase VOCs removal in a NTP-catalytic reactor. Chemical Engineering Journal, 2017, 320: 308–318 Li B H, Yu T H, Weng C Y, Yang C C, Lin C H, Lee S. Thermal and plasma synthesis of metal oxide nanoparticles from MOFs with SERS characterization. Vibrational Spectroscopy, 2016, 84: 146–152 Dou S, Dong C L, Hu Z, Huang Y C, Chen J L, Tao L, Yan D F, Chen D W, Shen C H, Chou S L, et al. Atomic-scale CoOx species in metal-organic frameworks for oxygen evolution reaction. Advanced Functional Materials, 2017, 27(36): 1702546