摘要Intensive light pulses with widths of about 10 ns were observed during the crack propagation by cleavage of crystalline sugar at atmospheric pressure. The observed light pulses were caused by a sequence of gas microdischarges (MDs). The pulses were detected in the UV/VIS and NIR wavelength ranges. First the light pulses appear in the UV/VIS wavelength range, and then after a delay of about 0.4–1.2 ns in the NIR wavelength range. This characteristic feature of MDs can be used for the characterization of crack propagation.
Abstract:Intensive light pulses with widths of about 10 ns were observed during the crack propagation by cleavage of crystalline sugar at atmospheric pressure. The observed light pulses were caused by a sequence of gas microdischarges (MDs). The pulses were detected in the UV/VIS and NIR wavelength ranges. First the light pulses appear in the UV/VIS wavelength range, and then after a delay of about 0.4–1.2 ns in the NIR wavelength range. This characteristic feature of MDs can be used for the characterization of crack propagation.
Sergej Aman**;Juergen Tomas;A. Streletskii
. Fast Modification of Microdischarge Emission Bands by Fracture of Sugar[J]. 中国物理快报, 2011, 28(8): 87802-087802.
Sergej Aman**, Juergen Tomas, A. Streletskii
. Fast Modification of Microdischarge Emission Bands by Fracture of Sugar. Chin. Phys. Lett., 2011, 28(8): 87802-087802.
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