Chromofore Poling in Thin Films of Organic Glasses. 1. Overview of Corona Discharge Application

Dalton, L.R., Lao, D., Olbricht, B.C., Benight, S., Bale, D.H., Davies, J.A., Ewy, T., Hammond, S.R., & Sullivan, P.A. (2010). Theory-inspired development of new nonlinear optical materials and their integration into silicon photonic circuits and devices. Optical Materials, 32, 658-668.10.1016/j.optmat.2009.02.002Search in Google Scholar

Comizolli, R.B. (1987). Uses of corona discharges in the semiconductor industry. J. Electrochem. Soc.: Solid-state science and technology, (February), 424-429.10.1149/1.2100472Search in Google Scholar

Shahin, M.M. (1969). Appl. Opt. Suppl., (3), 106.Search in Google Scholar

Shahin, M.M. (1969). Adv. Chem., 80, 48.Search in Google Scholar

Chen, J., & Davidson, J.H. (2002). Ozone production in the positive DC corona discharge: Model and comparison to experiments. Plasma Chemistry and Plasma Processing, 22 (4), 495-522.10.1023/A:1021315412208Search in Google Scholar

Chen, J., & Davidson, J. H. (2002). Electron density and energy distributions in the positive DC corona. Plasma Chemistry and Plasma Processing, 22 (2), June.Search in Google Scholar

Cooperman, G. (1960). A theory for space-charge-limited current with application to electrical precipitation. Trans. Amer. Inst. Eng., Part I, 79, 47-50.10.1109/TCE.1960.6368541Search in Google Scholar

Knoessen, A. (2002). Photoisomerization in polymer films in the presence of electro-static and optical fields. In " Photoreactive organic thin films", Sekkat Z. and Knoll N. (eds). Elsevier Science (USA), pp. 289-304.Search in Google Scholar

Peek, F.W. (1929). Dielectric Phenomena in High-Voltage Engineering (3^rd ed-n). New-York: McGraw-HillSearch in Google Scholar

Morrow, R. (1997). The theory of positive glow corona. J. Phys., 30 (22), 3099-3114.10.1088/0022-3727/30/22/008Search in Google Scholar

Raizer, Ju P. (1992). Phyzika gazovogo razrjada. Nauka, pp. 433-440.Search in Google Scholar

Kapcov, N.A. (1954). Elektronika. Nauka, pp. 371-384.Search in Google Scholar

Cooperman, G. (1981). A new current-voltage relation for duct precipitators valid for low and high current densities. IEEE Transactions on industry applications, 1A-17, March/April, pp. 236-239.10.1109/TIA.1981.4503931Search in Google Scholar

Sigmond, R.S. (1982). Simple approximate treatment of unipolar space-charge-dominated coronas: The Warburg law and the saturation current. J. Appl Phys., 53 (2), 891-898.10.1063/1.330557Search in Google Scholar

Mortazavi, M.A., Knoesen, A., & Kowel S.T. (1989). Second-harmonic generation and absorption studies of polymer - dye films oriented by corona-onset poling at elevated temperatures. J. Opt. Soc. Am., B6 4, 733-741.10.1364/JOSAB.6.000733Search in Google Scholar

Wintle, H.J. (1992). Unipolar wire-to-plane corona: accuracy of simple approximations. Journal of Electrostatics, 28 (2), 149-159.10.1016/0304-3886(92)90067-4Search in Google Scholar

Knoessen, A., Molau, N.E., Yankelevich, D.R., Mortazavi, M.A., & Dienes, A. (1992). Corona-poled nonlinear polymeric films: In situ electric field measurement, characterization and ultrashort-pulse applications. Int. J. of Nonlinear Optical Physics, 11 (1), pp. 73-102.10.1142/S0218199192000054Search in Google Scholar

Bauer, S. (1996). Poled polymers for sensors and photonic applications. Appl. Phys., 80 (10), 5531-5558.10.1063/1.363604Search in Google Scholar

Sessler, G.M. (1987). Physical properties of electrets. Electrets, Springer-Verlag, Berlin 13Search in Google Scholar

Suzuki, A., Matsuoka, Y., & Ikushima, A.J. (1991). Substrate effect on process of nonlinear optical polymer films. Japanese Journal of Applied Physics Part 2 - Letters 30 8B 15 Aug.10.1143/JJAP.30.L1493Search in Google Scholar

Kazjar, F., & Vitrant, G. (2003). Engeneering and application of functionalized polymers in nonlinear optics. Proc. SPIE Advanced Organic and Inorganic Optical Materials, 5122, 111-121.Search in Google Scholar

Moreno, R.A., & Gross, B. (1976). Measurement of potential buildup and decay, surface charge density, and charging currents of corona-charged polymer foil electrets. J. of Appl. Phys., 47 (8), 3397-3402.10.1063/1.323199Search in Google Scholar

Thomson, W., later Lord Kelvin (1898). Philos. Mag., 46, 82-120Search in Google Scholar

Zisman, W.A. (1932). Rev. Sci. Instr., 3, 367-370Search in Google Scholar

Vilitis, O., Fonavs, E., & Muzikante, I. (2001). A system for measuring surface potential by the Kelvin-Zisman vibrating capacitor probe. Latv. J. Phys. Techn. Sci., (5), 38-56.Search in Google Scholar

Gross, B., Giacometti, J.A., & Leal Ferreira, G.F. (1981). Corona method for investigation of charge storage and transport in dielectrics. Annual Report of Conf. On Insul. And Diel. Phenomena, 39-44.10.1109/EIDP.1981.7684621Search in Google Scholar

Fedosov, S.N., Sergeeva, A.E., & Giacometti, J.A. (1999). Pol. Liq. Cryst., 4017, 269.Search in Google Scholar

Fedosov, S. N., & Sergeeva, A. E. (2002). Corona poling of ferroelectric and nonlinear optical polymers. Moldavian J. of Phys. Sci., 2, 28-31.Search in Google Scholar

Giacometti, J.A., & Carvalho Campos, J.S. (1990). Constant current corona triode with grid voltage control. Application to polymer foil charging. Rev. Sci Instrum., 61 (3), 1143-1150.Search in Google Scholar

Giacometti, J.A. (1987). Radial current-density distributions and sample charge uniformity in a corona triode. J. Phys. D: Appl. Phys., 20, 675-682.10.1088/0022-3727/20/6/001Search in Google Scholar

Dao, P.T., Williams, D.J., McKenna, W.P., & Goppert-Baraducci, K. (1993). Constant current corona charging as a technique for poling organic nonlinear optical thin films and the effect of ambient gas. J. Appl. Phys., 73 (5) 1, 2043-2050.10.1063/1.353149Search in Google Scholar

Olivera, O.N., & Jr., Leal Ferreira, G.F. (1985). Grid - to plate current-voltage characteristics of a corona triode. Rev. Sci. Instrum., 56 (10), 1957-1961.10.1063/1.1138452Search in Google Scholar

Giacometti, J.A., & Reggi, A.S. (1993). Thermal pulse study of the polarization distributions produced in polyvinylidene fluoride by corona poling at constant current. J. Appl. Phys., 74 (5), 3357-3365.10.1063/1.354561Search in Google Scholar

Ribeiro, P.A., Raposo, M., Marat-Mendes, J.N., & Giacometti, J.A. (1992). Constant-current corona charging of biaxially stretched PVDF films in humidity-controlled atmospheres. IEEE Transactions on Electrical Insulation, 27 (4), 744-750.10.1109/14.155791Search in Google Scholar

Giacometti, J.A., & Oliveira, O.N., Jr. (1992). Corona charging of polymers. IEEE Transactions on Electrical Insulation, 27 (5), 924-943.10.1109/14.256470Search in Google Scholar

Ren, W., Bauer, S., Yilmaz, S., Wirges, W., & Gerhardt-Multhaupt, R. (1994). Optimized poling of nonlinear optical polymers based on dipole-orientation and dipole-relaxation studies. J. Appl. Phys., 75, 7211-7219.10.1063/1.356676Search in Google Scholar

Giacometti, J.A., Ribeiro, P.A., Raposo, M., Marat-Mendes, J.N., Carvalho Campos, J.S., & DeReggi, A.S. (1995). Study of poling behavior of biaxially stretched poly(vinylidene fluoride) films using the constant-current corona triode. J. Appl. Phys., 78 (9), 5597-5603.10.1063/1.359682Search in Google Scholar

Giacometti, J.A., Fedosov, S., & Costa M.M. (1999). Corona charging of polymers: Recent advances on constant current charging. Brazilian J. of Physics, 29 (2), 269-279.10.1590/S0103-97331999000200009Search in Google Scholar

Fedosov, S.N., Sergeeva, A.E., Giacometti, F.A., & Polischuk S.G. (2002). Switching of polarization and relaxation phenomena in corona poled ferroelectric polymers. Physics and chemistry of Solid State, (3), 413-417.Search in Google Scholar

Weinberg, Z.A., Matthies, D.L., Johnson W.C., & Lampert M.A. (1975). Measurement of the steady-state potential difference across a thin insulating film in corona discharge. Rev. Sci. Instrum., 46 (2), 201-203.10.1063/1.1134166Search in Google Scholar