R. F. Cooper scite author profile

R. F. Cooper

3Publications

61Citation Statements Received

12Citation Statements Given

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Providence College, University of Wisconsin System, Brown University

Publications

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Microwave Field Enhancement of Charge Transport in Sodium Chloride

1995

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We describe the results of experiments designed to test for microwave enhancement of vacancy transport processes in NaCl. Experimental results indicate that intrinsic vacancy mobility is not enhanced by microwave fields. Instead, the evidence strongly suggests an enhancement of the driving force for charge transport. The experimental results display features consistent with a recent theory for microwave-enhanced driving forces in ionic conductors. PACS numbers: 66.30.Hs, 68.35.Fx A growing body of experimental data suggests that microwave heating of ceramic materials leads to enhanced diffusion or solid-state reaction rates when compared with conventional heating at the same temperature [1][2][3][4][5][6][7]. If microwave heating is perceived as a purely thermal process (by rapid equilibration of microwave energy to thermal energy of the material), then it is difficult to explain how microwave and conventional furnace heating can result in markedly different reaction rates. The several explanations attempted for these experimental observations fall into one of two classes: (1) nonequilibrium thermodynamics, and (2) "nonthermal" phenomena.First, it has been argued that most temperature diagnostics only measure surface temperature and are therefore unreliable indicators of internal bulk temperatures. With microwave heating of low-loss materials, inverted temperature profiles (interior hotter than surface) occur at steady state as heat is lost from the surface, and it has been proposed that the internal temperatures responsible for the solid-state reactions exceed the measured surface temperatures by tens to hundreds of degrees Celsius. However, in some of the experiments referenced above (such as Ref.[3]), the sample dimensions and microwave absorption rates are both very small and therefore inconsistent with temperature differences of 50 -200'C between the surface and interior.Several nonthermal hypotheses are based on the idea that microwave field disturbances of sufficient magnitude might enhance high-energy, nonthermal "tails" on ion energy or lattice phonon distributions [8,9]. Such effects would appear as an enhancement of ionic mobility or a lessening of the activation energy for ionic motion in such a lattice. However, calculations based on the phonon kinetic (Boltzmann) equation [10] indicate that these phenomena will be negligible for the microwave field intensities present in Refs. [1 -7]. Most recently, Rybakov and Semenov [11] have proposed a model in which the microwave field induces nearsurface oscillatory fluxes of ionic point defects that are rectified, yielding a net "ponderomotive" (time-averaged nonzero) transport of charged defects. In effect, the microwave field induces a nonequilibrium concentration of vacancies in a small region near the surface of the ionic crystal. Mass flow is required to reach this nonequilibrium condition, and because the vacancies are charged, there is also an induced charge How. If these nonlinear forces are large enough, they could explain the observations of micr...

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Electromagnetic induction heating for cold wall rapid thermal processing

Thompson

Booske

Gianchandani

et al.

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An examination of athermal, photonic effects on boron diffusion and activation during microwave rapid thermal processing

Thompson

Booske

Cooper

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R. F. Cooper

Microwave Field Enhancement of Charge Transport in Sodium Chloride

Electromagnetic induction heating for cold wall rapid thermal processing

An examination of athermal, photonic effects on boron diffusion and activation during microwave rapid thermal processing

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