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http://dx.doi.org/10.3795/KSME-B.2008.32.11.832

High Power Laser Driven Shock Compression of Metals and Its Innovative Applications  

Lee, Hyun-Hee (서울대학교 기계항공공학부)
Gwak, Min-Cheol (서울대학교 기계항공공학부)
Choi, Ji-Hee (서울대학교 기계항공공학부)
Yoh, Jai-Ick (서울대학교 기계항공공학부 항공우주신기술연구소)
Publication Information
Transactions of the Korean Society of Mechanical Engineers B / v.32, no.11, 2008 , pp. 832-840 More about this Journal
Abstract
Ablation occurs at irradiance beyond $10^9\;W/cm^2$ with nanosecond and short laser pulses focused onto any materials. Phenomenologically, the surface temperature is instantaneously heated past its vaporization temperature. Before the surface layer is able to vaporize, underlying material will reach its vaporization temperature. Temperature and pressure of the underlying material are raised beyond their critical values, causing the surface to explode. The pressure over the irradiated surface from the recoil of vaporized material can be as high as $10^5\;MPa$. The interaction of high power nanosecond laser with a thin metal in air has been investigated. The nanosecond pulse laser beam in atmosphere generates intensive explosions of the materials. The explosive ejection of materials make the surrounding gas compressed, which form a shock wave that travels at several thousand meters per second. To understand the laser ablation mechanism including the heating and ionization of the metal after lasing, the temporal evolution of shock waves is captured on an ICCD camera through laser flash shadowgraphy. The expansion of shock wave in atmosphere was found to agree with the Sedov's self-similar spherical blast wave solution.
Keywords
Pulse Laser; Laser Ablation; Inverse Bremsstrahlung; Shock Wave; Plasma; Plasma Shield Effect;
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