EUV actinic brightfield mask microscopy for predicting printed defect images

SPIE Photomask Technology Pub Date : 2015-11-03 DOI:10.1117/12.2196966

K. Goldberg, M. Benk, A. Wojdyla, E. Verduijn, O. Wood, P. Mangat

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引用次数: 6

Abstract

Improving our collective understanding of extreme ultraviolet (EUV) photomask defects and the imaging properties of available defect imaging tools is essential for improving EUV mask defectivity, defect repair and mitigation, and for high-level strategic decision-making. In this work, we perform a qualitative comparison of twenty-five defects imaged with mask scanning electron microscopy (SEM), EUV actinic mask imaging, and wafer SEM imaging. All but two of the defect locations were first identified by non-actinic mask blank inspection, prior to patterning. The others were identified as repeating defects on the wafer. We find that actinic defect imaging is predictive of the wafer prints, with small-scale features clearly replicated. While some mask defect SEM images match the wafer prints, others print with a larger outline indicating the presence of sub-surface disruptions hidden from the SEM’s view. Fourteen other defects were subjected to an aerial image phase measurement method called Fourier Ptychography (FP). Although phase shifts were observed in the larger defects, the smaller defects in the dataset showed no significant phase shifting. We attribute this discrepancy to non-actinic mask blank inspection’s limited ability to detect small phase defects under normal operating conditions.

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用于预测印刷缺陷图像的EUV光化明场掩模显微镜

提高我们对极紫外(EUV)掩模缺陷和现有缺陷成像工具的成像特性的集体理解，对于提高EUV掩模缺陷、缺陷修复和缓解以及高层战略决策至关重要。在这项工作中，我们对用掩膜扫描电子显微镜(SEM)、EUV光化掩膜成像和晶圆扫描电子显微镜成像的25个缺陷进行了定性比较。除了两个缺陷位置外，所有的缺陷位置都是首先通过非光化掩模空白检查确定的，然后再进行图案制作。其他缺陷被认为是晶圆片上的重复缺陷。我们发现光化缺陷成像可以预测晶圆印刷，具有清晰复制的小尺寸特征。虽然一些掩膜缺陷的SEM图像与晶圆印刷相匹配，但其他打印的轮廓较大，表明存在隐藏在SEM视图中的次表面破坏。另外14个缺陷进行了称为傅里叶平面摄影(FP)的航空图像相位测量方法。虽然在较大的缺陷中观察到相移，但数据集中较小的缺陷没有明显的相移。我们将这种差异归因于非光化掩膜空白检测在正常操作条件下检测小相缺陷的能力有限。

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 Photomask Technology

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