激光超声法对加工硅片亚表面损伤深度的研究

A.A. Karabutov , N.B. Podymova
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引用次数: 7

摘要

本工作旨在应用激光超声方法对加工硅片的亚表面损伤深度进行无损评估。它是基于在基波长吸收调q Nd:YAG激光脉冲的不同激光激发机制:单晶硅中的浓度-变形机制和损伤层中的热弹性机制。由于激光脉冲作用时整个损伤层受热均匀,激光诱导超声信号的压缩相位幅值与损伤深度成正比。这个信号的稀薄阶段是由于受损层下面的单晶硅吸收了其余的激光能量而产生的。亚表面损伤深度与激光诱导超声信号压缩相位和稀疏相位幅值之比之间的经验关系可以用深度变化和相应的信号幅值扩展的线性函数来拟合。该关系可用于机械加工硅片亚表面损伤深度的原位定量无损评价;最小可靠可探测深度估计为0.15 ~ 0.2 μm。
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Study on the subsurface damage depth in machined silicon wafers by the laser-ultrasonic method

This work aims at applying the laser-ultrasonic method for nondestructive evaluation of the depth of the subsurface damage in machined silicon wafers. It is based on different mechanisms of laser excitation of ultrasound by absorption of Q-switched Nd:YAG laser pulses at the fundamental wavelength: the concentration–deformation mechanism in the single-crystalline silicon and the thermoelastic one in the damaged layer. Due to the uniform heating of the whole damaged layer during the laser pulse action the amplitude of the compression phase of the laser-induced ultrasonic signal is proportional to the damaged depth. The rarefaction phase of this signal arises by absorption of the rest of laser energy in the single-crystalline silicon beneath the damaged layer. The empirical relation between the depth of the subsurface damage and the ratio of the amplitudes of compression and rarefaction phases of the laser-induced ultrasonic signal can be fitted by a linear function within the depth variation and the corresponding spread of the signal amplitudes. This relation can be used for in situ quantitative nondestructive evaluation of the depth of the subsurface damage in machined silicon wafers; the minimal reliably detectable depth is estimated at the level of 0.15–0.2 μm.

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Contents Editorial Board Editorial Board Contents Comparison of surface-based and image-based quality metrics for the analysis of dimensional computed tomography data
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