Problems of and Solutions for Coating Techniques for TEM Sample Preparation on Ultra Low-k Dielectric Devices after Progressive-FIB Cross-section Analysis

2018 IEEE International Symposium on the Physical and Failure Analysis of Integrated Circuits (IPFA) Pub Date : 2018-07-01 DOI:10.1109/IPFA.2018.8452598

Yanlin Pan, Yuzhe Zhao, P. K. Tan, Z. Mai, F. Rival, J. Lam

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引用次数: 1

Abstract

This paper presents the impact of coating techniques for TEM sample preparation on ultra low-k dielectric devices after progressive-FIB cross-section analysis. The ultra low-k materials used as inter-metal dielectrics (IMD) has a k value less than 2.6. In the experimental study on three commonly used protective coatings (sputtered Pt, e-beam deposited insulator and PECVD oxide) for the 28 nm technology node with ultra low-k IMD, PECVD oxide coating was found to be an ideal choice for the TEM sample preparation with the least low-k dielectric deformation or damage. In-situ e-beam deposited insulator in a dual-beam FIB tool equipped with a GIS for insulator deposition is a convenient and commonly used method. However, the e-beam can introduce a considerable damage to the ultra low-k IMD during the e-beam deposition. Sputtered Pt can achieve a damage-free profile of an ultra low-k IMD, but we have to sacrifice certain portion of the target area in the final FIB cleaning process during TEM sample preparation. This makes sputtered Pt not suitable for the TEM sample preparation on a defect with a small size (<100 nm).

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逐级fib分析超低k介电器件TEM样品制备涂层技术存在的问题及解决方法

通过逐级fib截面分析，研究了TEM样品制备的涂层技术对超低k介电器件的影响。作为金属间电介质(IMD)的超低k材料的k值小于2.6。在超低k IMD的28 nm技术节点上，对三种常用的保护涂层(溅射Pt、电子束沉积绝缘体和PECVD氧化物)进行了实验研究，发现PECVD氧化物涂层是制备TEM样品的理想选择，具有最小的低k介电变形或损伤。在双梁FIB工具中采用原位电子束沉积绝缘子是一种方便且常用的方法。然而，在电子束沉积过程中，电子束会对超低k IMD造成相当大的破坏。溅射Pt可以实现超低k IMD的无损伤轮廓，但在TEM样品制备过程中，我们必须在最终的FIB清洗过程中牺牲目标区域的某些部分。这使得溅射Pt不适合在小尺寸缺陷(<100 nm)上制备TEM样品。

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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2018 IEEE International Symposium on the Physical and Failure Analysis of Integrated Circuits (IPFA)

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