参考文献

[1]　张锐，刘鹏，詹如娟. 大气压辉光放电研究现状及应用前景.物理，2004，33（6）： 430-434.

[2]　竹涛. 低温等离子体技术处理工业源VOCs.北京： 冶金工业出版社，2015.

[3]　Akishev Y，Goossens O，Callebaut T，et al. The influence of electrode geometry and gas flow on corona-to-glow and glow-to-spark threshold currents in air. Journal of Physics D Applied Physics，2001，34（18）： 2875-2882.

[4]　Akishev Y S，Deryugin A A，Kochetov I V，et al. DC glow discharge in air flow at atmospheric pressure in connection with waste gases treatment. Journal of the Optical Society of America A，1999，16（3）： 467-474.

[5]　Akishev Y S，Grushin M E，Kochetov I V，et al. Transition of a multipin negative corona in atmospheric air to a glow discharge. Plasma Physics Reports，2000，26（2）： 157-163.

[6]　Andre P，Barinov Y，Faure G，et al. Experimental study of discharge with liquid non-metallic （tap-water） electrodes in air at atmospheric pressure. Journal of Physics D： Applied Physics，2001，34（24）： 3456-3465.

[7]　Denisova N V，Postnikov B V，Fomin V M. Transverse glow discharges in supersonic air and methane flows. Plasma Physics Reports，2006，32（3）： 254-261.

[8]　Ding W，Mccorkle D L，Pinnaduwage L A. Enhanced formation of negative ions by electron attachment to highly excited molecules in a flowing afterglow plasma. Journal of Applied Physics，1998，84（6）： 3051-3058.

[9]　Eliasson B，Kogelschatz U. Modeling and applications of silent discharge plasmas. IEEE Transactions on Plasma Science，1991，19（2）： 309-323.

[10]　Fridman，Alexander A，Kennedy，et al. Plasma physics and engineering.Abingdon： Taylor & Francis Routledge，2004.

[11]　Goossens O，Callebaut T，Akishev Y，et al. The DC glow discharge at atmospheric pressure. IEEE Transactions on Plasma Science，2002，30（1）： 176-177.

[12]　Jiang C，Mohamed A A H，Stark R H，et al. Removal of volatile organic compounds in atmospheric pressure air by means of direct current glow discharges. IEEE Transactions on Plasma Science，2005，33（4）： 1416-1425.

[13]　Kanazawa S，Kogoma M，Moriwaki T，et al. Stable glow plasma at atmospheric pressure. Journal of Physics D： Applied Physics，1988，21（5）： 838-840.

[14]　Kanazawa S，Kogoma M，Okazaki S，et al. Glow plasma treatment at atmospheric pressure for surface modification and film deposition. Nuclear Instruments & Methods in Physics Research，1989，37-38（1）： 842-845.

[15]　Kang W S，Jin M P，Kim Y，et al. Numerical study on influences of barrier arrangements on dielectric barrier discharge characteristics. IEEE Transactions on Plasma Science，2003，31（4）： 504-510.

[16]　Kohno H，Berezin A A，Chang J S，et al. Destruction of volatile organic compounds used in a semiconductor industry by a capillary tube discharge reactor. IEEE Transactions on Industry Applications，1995，34（5）： 953-966.

[17]　Koutsospyros A，Yin S M，Christodoulatos C，et al. Destruction of hydrocarbons in non-thermal，ambient-pressure，capillary discharge plasmas. International Journal of Mass Spectrometry，2004，233（1-3）： 305-315.

[18]　Koutsospyros A D，Yin S M，Christodoulatos C，et al. Plasmochemical degradation of volatile organic compounds （VOC） in a capillary discharge plasma Reactor. IEEE Transactions on Plasma Science，2005，33（1）： 42-49.

[19]　Krasnoperov L N，Krishtopa L G，Bozzelli J W. Study of volatile organic compounds destruction by dielectric barrier corona discharge. 1997，2： 248-256.

[20]　Kröpke St，Akishev YuS，Holländer A. Atmospheric pressure DC glow discharge for polymer surface treatment. Surface and Coatings Technology，2001，142-144： 512-516.

[21]　Lerner B，Birmingham J，Tonkyn R. Decomposition of trichloroethylene by a large scale，high flow packed-bed gas phase corona reactor，1995.

[22]　Lu X，Leipold F，Laroussi M. Optical and electrical diagnostics of a non-equilibrium air plasma. Journal of Physics D Applied Physics，2003，36（21）： 2662-2666.

[23]　Machala Z，Marode E，Morvov􀅡 M，et al. DC glow discharge in atmospheric air as a source for volatile organic compounds abatement. Plasma Processes & Polymers，2005，2（3）： 152-161.

[24]　Mccorkle D L，Ding W，Ma C Y，et al. Dissociation of benzene and methylene chloride based on enhanced dissociative electron attachment to highly excited molecules. Journal of Physics D Applied Physics，1998，32（1）： 46-54.

[25]　Mccorkle D L，Ding W，Ma C Y，et al. Dissociation of benzene in a pulsed glow discharge[J]. Journal of Applied Physics，1999，86（7）： 3550-3557.

[26]　Mezei P，Cserfalvi T，Jnossy M. On the pressure dependence of the positive column cross section in high-pressure glow discharges. Journal of Physics D Applied Physics，2001，34（12）：1914-1918.

[27]　Neuhauser R G，Siglow K，Neusser H J. High n rydberg spectroscopy of benzene： dynamics，ionization energy and rotational constants of the cation. Journal of Chemical Physics，1997，106（3）： 896-907.

[28]　Penetrante B M，Hsiao M C，Bardsley J N. Comparison of non-thermal plasma techniques for abatement of volatile organic compounds and nitrogen oxides. Office of Scientific & Technical Information Technical Reports，1996.

[29]　Pinnaduwage L A，Ding W，Mccorkle D L. Enhanced electron attachment to highly excited molecules using a plasma mixing scheme. Applied Physics Letters，1997，71（25）： 3634-3636.

[30]　Pinnaduwage L A，Zhu Y. Long-time stability of superexcited high Rydberg molecular states. Chemical Physics Letters，1997，277（1-3）： 147-152.

[31]　Roth J R，Tsai P P，Liu C Y，et al. One atmosphere，uniform glow discharge plasma. US，PCT： 5414324，1995.

[32]　Schoenbach K H，Tessnow T，Verhappen R. High pressure hollow cathode discharges. IEEE International Conference on Plasma Science，1997.

[33]　Stark R H，Schoenbach K H. Direct current high-pressure glow discharges. Journal of Applied Physics，1999，85（4）： 2075-2080.

[34]　Stark R H，Schoenbach K H. Electron heating in atmospheric pressure glow discharges. Journal of Applied Physics，2001，89（7）： 3568-3572.

[35]　Stark R H，Schoenbach K H. Direct current glow discharges in atmospheric air. Plasmadynamic and Lasers Conference，1999.

[36]　Vertriest R，Morent R，Dewulf J，et al. Multi-pin-to-plate atmospheric glow discharge for the removal of volatile organic compounds in waste air. Plasma Sources Science & Technology，2003，12（3）： 412-416.

[37]　Vitale S A，Hadidi K，Cohn D R，et al. The effect of a carbon-carbon double bond on electron beam-generated plasma decomposition of trichloroethylene and 1，1，1-trichloroethane. Plasma Chemistry adn Plasma Processing，1997，17（1）： 59-78.

[38]　Varakin V N，Kuzyakov Y Y. Photoprocesses induced by short-wavelength excimer laser radiation in adsorbed halomethane molecules. High Energy Chemistry，2008，42（2）： 145-150.

[39]　Wang J Y，Xia G G，Huang A，et al. CO2 decomposition using glow discharge plasmas. Journal of Catalysis，1999，185（1）： 152-159.

[40]　Yin S M，Christodoulatos C，Becker K，et al. Destruction of environmental air contaminants using a non-thermal，ambient-pressure capillary plasmas. Protection and Restoration of the Environment Vii-Mykonos，2004.

[41]　Yu L，Laux C O，Packan D M，et al. Direct-current glow discharges in atmospheric pressure air plasmas. Journal of Applied Physics，2002，91（5）： 2678-2686.