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Lin S. L.,
Robson R. E., Mason E. A.
The Journal of Chemical Physics. 1979 71(8). p.3483
Swarm Analysis by Using Transport Equations. I. Steady-State Swarm Behavior of Electrons in a Uniform Medium
Dote Toshihiko, Shimada Masatoshi
Journal of the Physical Society of Japan. 1980 49(4). p.1434
Transport Property of Electrons in Gases under Electric Field 1. Lateral Diffusion Coefficient
Ikuta Nobuaki,
Itoh Hidenori,
Okano Nobuyuki, Yamamoto Kōji
Journal of the Physical Society of Japan. 1985 54(7). p.2485
Electron–Molecule Interactions and their Applications (1984)
Monte Carlo simulations of electron drift velocities in binary inert gas mixtures
Davies A J,
Dutton J,
Evans C J,
Goodings A, Stewart P K
Journal of Physics D: Applied Physics. 1984 17(2). p.287
Kinetic theory of drift-tube experiments with polyatomic species
Viehland L.A.,
Lin S.L., Mason E.A.
Chemical Physics. 1981 54(3). p.341
Monte Carlo Simulation of Electron Swarm in a Model Gas: Transverse and Longitudinal Diffusion Coefficients
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Journal of the Physical Society of Japan. 1986 55(8). p.2500
Comments on electron transport in gases with particular reference to argon
Brennan M. J., Ness K. F.
Il Nuovo Cimento D. 1992 14(9). p.933
Attachment of low-energy electrons to HCl
Petrović Z. Lj.,
Wang W. C., Lee L. C.
Journal of Applied Physics. 1988 64(4). p.1625
Spherical-harmonics decomposition of the Boltzmann equation for charged-particle swarms in the presence of both electric and magnetic fields
Ness K. F.
Physical Review E. 1993 47(1). p.327
Convenient expressions of diffusion coefficients for free electrons in gases in the presence of Ramsauer effects
Cavalleri G., Mauri G.
Physical Review B. 1988 37(12). p.6868
Influence of the excitation frequency increase on a fluid model of the capacitively coupled argon plasma
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Computer Physics Communications. 2021 267 p.108057
Kinetic phenomena in electron transport in radio-frequency fields
Petrović Z.Lj.,
Raspopović Z.M.,
Dujko S., Makabe T.
Applied Surface Science. 2002 192(1-4). p.1
A phaseshift analysis of experimental angular distributions of electrons elastically scattered from He, Ne and Ar over the range 0.5 to 20 eV
Williams J F
Journal of Physics B: Atomic and Molecular Physics. 1979 12(2). p.265
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Schmidt B., Polenz S.
Nuclear Instruments and Methods in Physics Research Section A: Accelerators, Spectrometers, Detectors and Associated Equipment. 1988 273(2-3). p.488
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Cavalleri G.
Il Nuovo Cimento B Series 11. 1981 62(1). p.41
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Pinhão N R,
Donkó Z,
Loffhagen D,
Pinheiro M J, Richley E A
Plasma Sources Science and Technology. 2004 13(4). p.719
Comparison of the results of Monte Carlo simulations with experimental data for electron swarms in from moderate to very high electric field to gas density ratios
Stojanovic V D, Petrovic Z Lj
Journal of Physics D: Applied Physics. 1998 31(7). p.834
Boltzmann equation analysis of electron swarms for model cases with power-law elastic scattering
Itoh H,
Ikuta N, Toyota K
Journal of Physics D: Applied Physics. 1983 16(3). p.293
A unidimensional Monte Carlo simulation of electron drift velocities and electroluminescence in argon, krypton and xenon
Dias T H V T,
Stauffer A D, Cone C A N
Journal of Physics D: Applied Physics. 1986 19(4). p.527
Multi-term solutions of Boltzmann’s equation for electrons in the real gases Ar, CH4 and CO2
Braglia G. L.,
Wilhelm J., Winkler E.
Lettere Al Nuovo Cimento Series 2. 1985 44(6). p.365
Variations in electron transport in argon with temperature near the Ramsauer-Townsend minimum
Makabe T, Mori T
Journal of Physics D: Applied Physics. 1982 15(8). p.1395
Long-time behavior of the Lorentz electron gas in a constant, uniform electric field
Piasecki J., Wajnryb E.
Journal of Statistical Physics. 1979 21(5). p.549
Calculation of electron transport coefficients in counting gas mixtures
Mathieson E., El Hakeem N.
Nuclear Instruments and Methods. 1979 159(2-3). p.489
A calculation method for estimating a cross section using a Boltzmann equation analysis
Taniguchi T,
Suzuki M,
Kawamura K,
Noto F, Tagashira H
Journal of Physics D: Applied Physics. 1987 20(8). p.1085
Effects of vibrationally excited N2 molecules on dielectric breakdown properties of SF6-N2 mixtures
Tang Nian,
Guo Ze,
Zhou Yongyan, Li Li
AIP Advances. 2018 8(10).
Monte Carlo calculation of electron transport coefficients in counting gas mixtures
Fraser G.W., Mathieson E.
Nuclear Instruments and Methods in Physics Research Section A: Accelerators, Spectrometers, Detectors and Associated Equipment. 1986 247(3). p.544
The diffusion and drift of electrons in gases
Braglia G.L., Baiocchi A.
Physica B+C. 1978 95(2). p.227
Momentum-transfer cross section for electron-helium collisions in the range 4-12 eV
Milloy H. B., Crompton R. W.
Physical Review A. 1977 15(5). p.1847
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