Li Guangjiang, Claveau Elliot L, Jawla Sudheer K, Schaub Samuel C, Shapiro Michael A, Temkin Richard J
Plasma Science and Fusion Center, Massachusetts Institute of Technology, Cambridge, Massachusetts 02139, USA.
Air Force Research Laboratory, Directed Energy Directorate, Kirtland Air Force Base, Albuquerque, New Mexico, USA.
IEEE Trans Terahertz Sci Technol. 2023 Jul;13(4):354-361. doi: 10.1109/tthz.2023.3270671. Epub 2023 Apr 27.
The reflectance and transmittance of Si and GaAs wafers irradiated by a 6 ns pulsed, 532 nm laser have been studied for s- and p-polarized 250 GHz radiation as a function of laser fluence and time. The measurements were carried out using precision timing of the and signals, allowing an accurate determination of the absorptance where . Both wafers had a maximum reflectance above 90% for a laser fluence . Both also showed an absorptance peak of ~50% lasting ~2 ns during the risetime of the laser pulse. Experimental results were compared with a stratified medium theory using the Vogel model for the carrier lifetime and the Drude model for permittivity. Modeling showed that the large absorptance at the early part of the rise of the laser pulse was due to the creation of a lossy, low carrier density layer. For Si, the measured and were in very good agreement with theory on both the nanosecond time scale and the microsecond scale. For GaAs, the agreement was very good on the nanosecond scale but only qualitatively correct on the microsecond scale. These results may be useful for planning applications of laser driven semiconductor switches.
研究了6纳秒脉冲、532纳米激光辐照下的硅和砷化镓晶圆对s偏振和p偏振250吉赫兹辐射的反射率和透射率,它们是激光能量密度和时间的函数。测量是通过对信号进行精确计时来进行的,从而能够准确确定吸收率,其中。对于激光能量密度,两种晶圆的最大反射率均高于90%。两者还在激光脉冲上升时间期间显示出持续约2纳秒、吸收率峰值约为50%的情况。实验结果与使用Vogel模型计算载流子寿命、Drude模型计算介电常数的分层介质理论进行了比较。建模表明,激光脉冲上升初期的高吸收率是由于形成了一个有损、低载流子密度层。对于硅,在纳秒时间尺度和微秒时间尺度上,测量得到的和与理论都非常吻合。对于砷化镓,在纳秒时间尺度上吻合得非常好,但在微秒时间尺度上仅定性正确。这些结果可能有助于规划激光驱动半导体开关的应用。