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Essence of thermal convection for physical vapor transport of mercurous chloride in regions of high vapor pressures  

Kim, Geug-Tae (Department of Nano-Bio Chemical Engineering, Hannam University)
Lee, Kyong-Hwan (Fossil Energy Environment Research Department, Korea Institute of Energy Research)
Choi, Jeong-Gil (Department of Nano-Bio Chemical Engineering, Hannam University)
Publication Information
Journal of the Korean Crystal Growth and Crystal Technology / v.17, no.6, 2007 , pp. 231-237 More about this Journal
Abstract
For an aspect ratio (transport length-to-width) of 5, Pr=3.34, Le=0.078, Pe=4.16, Cv=1.01, $P_B=50$ Torr, only thermally buoyancy-driven convection ($Gr=4.83{\times}10^5$) is considered in this study in spite of the disparity in the molecular weights of the component A ($Hg_2Cl_2$) and B which would cause thermally and/or solutally buoyancy-driven convection. The crystal growth rate and the maximum velocity vector magnitude are decreased exponentially for $3{\le}Ar{\le}5$, for (1) adiabatic walls and (2) the linear temperature profile, with a fixed source temperature. This is related to the finding that the effects of side walls tend to stabilize convection in the growth reactor. The rate for the linear temperature profiles walls is slightly greater than for the adiabatic walls far varied temperature differences and aspect ratios. With the imposed thermal profile, a fixed source region, both the rate and the maximum velocity vector magnitude increase linearly with increasing the temperature difference for $10{\le}{\Delta}T{\le}50K$.
Keywords
Mercurous chloride; Thermal convection; Aspect ratio; Physical vapor transport;
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