Two-dimensional low-coherence interferometry for the characterization of nanometer wafer topographies

SPIE Photonics Europe Pub Date : 2016-05-03 DOI:10.1117/12.2227887

C. Taudt, T. Baselt, B. Nelsen, H. Assmann, A. Greiner, E. Koch, P. Hartmann

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引用次数: 8

Abstract

Within this work a scan-free, low-coherence interferometry approach for surface profilometry with nm-precision is presented. The basic setup consist of a Michelson-type interferometer which is powered by a super-continuum light-source (Δλ= 400-1700 nm). The introduction of an element with known dispersion delivers a controlled phase variation which can be detected in the spectral domain and used to reconstruct height differences on a sample. In order to enable scan-free measurements, the interference signal is spectrally decomposed with a grating and imaged onto a two-dimensional detector. One dimension of this detector records spectral, and therefore height information, while the other dimension stores the spatial position of the corresponding height values. In experiments on a height standard, it could be shown that the setup is capable of recording multiple height steps of 101 nm over a range of 500 m with an accuracy of about 11.5 nm. Further experiments on conductive paths of a micro-electro-mechanical systems (MEMS) pressure sensor demonstrated that the approach is also suitable to precisely characterize nanometer-sized structures on production-relevant components. The main advantage of the proposed measurement approach is the possibility to collect precise height information over a line on a surface without the need for scanning. This feature makes it interesting for a production-accompanying metrology.

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二维低相干干涉法表征纳米晶圆形貌

在这项工作中，提出了一种无扫描、低相干干涉测量法，用于纳米精度的表面轮廓测量。基本装置由一个迈克尔逊型干涉仪组成，该干涉仪由超连续光源(Δλ= 400-1700 nm)供电。引入具有已知色散的元素，可以在光谱域中检测到可控的相位变化，并用于重建样品上的高度差。为了实现无扫描测量，用光栅对干扰信号进行频谱分解，并在二维探测器上成像。该探测器的一个维度记录光谱，从而记录高度信息，而另一个维度存储相应高度值的空间位置。在高度标准的实验中，可以证明该装置能够在500 m范围内记录101 nm的多个高度步长，精度约为11.5 nm。在微机电系统(MEMS)压力传感器的导电路径上进行的进一步实验表明，该方法也适用于精确表征生产相关部件上的纳米尺寸结构。所提出的测量方法的主要优点是可以在不需要扫描的情况下在表面上的一条线上收集精确的高度信息。这个特性对于伴随生产的计量来说很有趣。

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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SPIE Photonics Europe

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