Effect of sample temperature and laser ablation angle on optical emission and acoustic signals from laser-induced Zirconium plasma

Batsaikhan, M.; 大場 弘則  ; 狩野 貴宏 ; 赤岡 克昭 ; 若井田 育夫  

Batsaikhan, M.; Oba, Hironori; Karino, Takahiro; Akaoka, Katsuaki; Wakaida, Ikuo

A fiber-coupled, acoustic-wave-assisted microchip laser-induced breakdown spectroscopy system (AW-mLIBS) was developed to analyze the elemental composition and surface imaging. In this study, we measured the dependence of sample temperature and laser ablation angle on the laser-induced plasma-optical emission and LIP-acoustic signal. The intensity of the laser-induced plasma-optical emission and ablated mass at three different temperatures and eight different laser ablation angles were estimated using a zirconium sample. Simultaneously, we investigated the laser-induced plasma-acoustic signal amplitude, propagation speed, and shape by synchronizing the AW-mLIBS system with a high-speed camera. The results revealed that the laser-induced plasma-optical emission increases with increasing temperature and is unaffected by laser ablation angle up to 40 degree because the amount of the ablated mass was similar and the plasma. Additionally, no considerable variation in plasma temperature obtained using the Boltzmann method over the sample temperature. However, the propagation speed of the laser-induced plasma-acoustic signal differs with temperature but has marginal angular dependence because the laser-induced plasma-acoustic signal propagates as semispherical. Furthermore, small and no considerable changes observed in the laser-induced plasma-acoustic signal amplitude up to 100 degree Celsius, and the laser ablation angle showed a similar tendency to that of the laser-induced plasma-optical emission.