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Rotationally resolved hot atom collisional excitation of CO2(0001) by time-resolved diode laser spectroscopy (1986)

O'Neill, James A. ; Wang, Chen Xi ; Cai, Ji Ye ; [et al.]

College Park, Md. : American Institute of Physics (AIP)

The Journal of Chemical Physics 85 (1986), S. 4195-4197

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ISSN: 1089-7690

Source: AIP Digital Archive

Topics: Physics , Chemistry and Pharmacology

Notes: A tunable infrared diode laser was used to study the nascent rotationa distribution of CO2 molecules produced directly in the 0001 excited state as a result of collisions with hot hydrogen atoms formed in the UV photolysis of H2S.(AIP)

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1063/1.450893

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Heat transfer from a rarefied plasma flow to a metallic or nonmetallic particle (1986)

Chen, Xi ; He, Ping

Springer

Plasma chemistry and plasma processing 6 (1986), S. 313-333

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ISSN: 1572-8986

Keywords: Heat transfer to metallic and nonmetallic particles ; free-molecule flow regime ; two-temperature plasma ; reduced pressure ; analysis

Source: Springer Online Journal Archives 1860-2000

Topics: Chemistry and Pharmacology , Mechanical Engineering, Materials Science, Production Engineering, Mining and Metallurgy, Traffic Engineering, Precision Mechanics , Technology

Notes: Abstract Heat transfer from a plasma flow to a metallic or nonmetallic spherical particle is studied in this paper for the extreme case of free-molecule flow regime. Analytical expressions are derived for the heat flux due to, respectively, atoms, ions, and electrons and for the floating potential on the sphere exposed to a two-temperature plasma flow. It has been shown that the local or average heat flux density over the whole sphere is independent of the sphere radius and approximately in direct proportion to the gas pressure. The presence of a macroscopic relative velocity between the plasma and the sphere causes substantially nonuniform distributions of the local heat flux and enhances the total heat flux to the sphere. The heat flux is also enhanced by the gas ionization. Appreciable difference between metallic and nonmetallic spheres is found in the distributions along the oncoming flow direction of the floating potential and of the local heat flux densities due to ions and electrons. The total heat flux to the whole sphere is, however, almost the same for these different spheres. For a fixed value of the electron temperature, the heat flux decreases with increasing temperature ratio Te/Th.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00565548

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Heat transfer to a particle under plasma conditions with vapor contamination from the particle (1985)

Chen, Xi ; Chyou, Y. P. ; Lee, Y. C. ; [et al.]

Springer

Plasma chemistry and plasma processing 5 (1985), S. 119-141

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ISSN: 1572-8986

Keywords: Heat and mass transfer ; thermal plasma ; vapor contamination effect ; analytical studies

Source: Springer Online Journal Archives 1860-2000

Topics: Chemistry and Pharmacology , Mechanical Engineering, Materials Science, Production Engineering, Mining and Metallurgy, Traffic Engineering, Precision Mechanics , Technology

Notes: Abstract Heat transfer to a copper particle immersed into an argon plasma is considered in this paper, including the effects of contamination of the plasma (transport coefficients) by copper vapor from the particle. Except for cases of high plasma temperatures, the vapor content in the plasma is shown to have a considerable influence on heat transfer to a nonevaporating particle, and, to a lesser extent, on heat transfer to an evaporating particle. Evaporation itself reduces heat transfer to a particle substantially as shown in a previous paper [Xi Chen and E. Pfender, Plasma Chem. Plasma Process.,2, 185 (1982)]. Comparisons of the calculated results with those based on a method suggested in the above reference show that the simplified assumptions employed, i.e., that the surface temperature is equal to the boiling point and that plasma properties based on a fixed composition are applicable, can be employed to simplify calculations for many cases. This study reveals that a considerable portion of a particle must be vaporized before a steady concentration distribution is established around the particle.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00566210

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Drag on a metallic or nonmetallic particle exposed to a rarefied plasma flow (1989)

Chen, Xi ; Chen, Xiaoming

Springer

Plasma chemistry and plasma processing 9 (1989), S. 387-408

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ISSN: 1572-8986

Keywords: Particle drag force ; free-molecule flow regime ; pressure effect ; two-temperature plasma ; analysis

Source: Springer Online Journal Archives 1860-2000

Topics: Chemistry and Pharmacology , Mechanical Engineering, Materials Science, Production Engineering, Mining and Metallurgy, Traffic Engineering, Precision Mechanics , Technology

Notes: Abstract Drag force on a metallic or nonmetallic spherical particle exposed to a plasma flow is studied for the extreme case of a free-molecule regime. Analytical expressions are derived for the drag components due to, respectively, atoms, ions, and electrons and for the total drag on the whole sphere due to all the gas species. It has been shown that the drag is proportional to the square of the particle radius or the drag coefficient is independent of the particle radius. At low gas temperatures with a negligible degree of ionization, the drag is caused mainly by atoms and could be predicted by using the well-known drag expression given in ordinary-temperature rarefied gas dynamics. On the other hand, the drag is caused mainly by ions at high plasma temperatures with a great degree of ionization. The contribution of electrons to the total drag is always negligible. Ignoring gas ionization at high plasma temperatures would overestimate the particle drag. There is a little difference between metallic and nonmetallic spheres in their total drag forces, with a slightly higher value for a metallic sphere at high plasma temperatures, but usually such a small difference could be neglected in engineering calculations. The drag increases rapidly with increasing gas pressure or oncoming speed ratio. For a two-temperature plasma, the drag increases at low electron temperatures but decreases at high electron temperatures with the increase in the electron/heavy-particle temperature ratio.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF01083674

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