Measurement of surface topographies in the nm-range for power chip technologies by a modified low-coherence interferometer

SPIE OPTO Pub Date : 2016-03-16 DOI:10.1117/12.2212913

C. Taudt, T. Baselt, B. Nelsen, H. Assmann, A. Greiner, Edmund Koch, Peter Hartmann

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Abstract

This work introduces a modified low-coherence interferometry approach for nanometer surface-prolometry. The key component of the interferometer is an element with known dispersion which defines the measurement range as well as the resolution. This dispersive element delivers a controlled phase variation which can be detected in the spectral domain and used to reconstruct height differences on a sample. In the chosen setup, both axial resolution and measurement range are tunable by the choice of the dispersive element. The basic working principle was demonstrated by a laboratory setup equipped with a supercontinuum light source ( Δλ= 400-1700 nm). Initial experiments were carried out to characterize steps of 101 nm on a silicon height standard. The results showed that the system delivers an accuracy of about 11.8 nm. These measurements also served as a calibration for the second set of measurements. The second experiment consisted of the measurement of the bevel of a silicon wafer. The modified low-coherence interferometer could be utilized to reproduce the slope on the edge within the previously estimated accuracy. The main advantage of the proposed measurement approach is the possibility to collect data without the need for mechanically moving parts.

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用改进的低相干干涉仪测量功率芯片技术纳米范围内的表面形貌

本文介绍了一种改进的低相干干涉法用于纳米表面测量。干涉仪的关键部件是已知色散的元件，色散决定了测量范围和分辨率。这种色散元件提供可控的相位变化，可以在光谱域中检测到，并用于重建样品上的高度差。在所选择的设置中，轴向分辨率和测量范围都可以通过选择色散元件来调节。在超连续光源(Δλ= 400-1700 nm)的实验装置上验证了其基本工作原理。在硅高度标准上对101 nm的步长进行了初步的表征。结果表明，该系统的精度约为11.8 nm。这些测量也可作为第二组测量的校准。第二个实验是测量硅片的斜角。利用改进后的低相干干涉仪可以在先前估计的精度范围内再现边缘上的斜率。所提出的测量方法的主要优点是可以在不需要机械运动部件的情况下收集数据。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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