Infrared-induced temperature distributions of solid D2 ices

doi:10.1088/1674-1056/22/3/034401

Abstract A specific-wavelength infrared (IR) light (λ=3140 nm) was irradiated into a solid D₂ ice prepared in a cylinder target cell. The temperature in the solid D₂ ice oscillated periodically with a high amplitude when irradiated by the IR light. The temperature oscillation has been well explained based on the two-dimensional heat transfer theory plus the IR-irradiation effect. The transmission optical imaging reveals that such a temperature oscillation is favorable to recrystallize the solid D₂ ice from multicrystal to quasi single crystal. This suggests an efficient method to layer the solid hydrogen-isotope ice for the inertial-confinement-fusion (ICF) experiments.

Keywords: heat transfer solid deuterium infrared irradiation

Received: 15 July 2012
Revised: 03 September 2012
Accepted manuscript online:

PACS:	44.10.+i	(Heat conduction)
	67.80.F-	(Solids of hydrogen and isotopes)
	87.50.W-

Corresponding Authors: Lei Hai-Le
E-mail: hailelei@caep.ac.cn

Cite this article:

Bi Peng (毕鹏), Xie Duan (谢端), Lin Wei (林伟), Wang Kai (王凯), Liu Jiang-Ping (刘江平), Tang Yong-Jian (唐永建), Yang Xiang-Dong (杨向东), Lei Hai-Le (雷海乐) Infrared-induced temperature distributions of solid D₂ ices 2013 Chin. Phys. B 22 034401

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Infrared-induced temperature distributions of solid D₂ ices