通过扫描SQUID显微镜在芯片优先的MCM中定位电源到接地短路

2000 IEEE International Reliability Physics Symposium Proceedings. 38th Annual (Cat. No.00CH37059) Pub Date : 2000-04-10 DOI:10.1109/RELPHY.2000.843949

W. Vanderlinde, M.E. Cheney, E. B. McDaniel, K. L. Skinner, L. A. Knauss, B. M. Frazier, H. Christen

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引用次数: 6

摘要

我们证明了扫描SQUID(超导量子干涉器件)显微镜是一种快速简便的方法，可以在一系列芯片优先的MCM(多芯片模块)样品中找到电源对地短路的位置。先前的工作表明，扫描SQUID显微镜能够定位C4芯片载体和球栅阵列封装中的短路，但是没有进行物理分析来验证(假定的)故障位置。在本工作中，利用SQUID显微镜定位了芯片优先的MCM中的短区，并通过机械横截面进行了确认。当使用SQUID显微镜发现第二个MCM中的短路并使用激光进行修复时，电源对地电阻增加了1000多倍，使零件符合规格。发射显微镜等技术在检测这些器件中的短路电流路径方面是不成功的。因此，扫描SQUID显微镜是唯一已知的定位和修复该产品缺陷的方法。

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Localizing power to ground shorts in a chips-first MCM by scanning SQUID microscopy

We demonstrate that scanning SQUID (Superconducting Quantum Interference Device) microscopy is a fast and easy method for finding the location of power-to-ground shorts in a series of chip-first MCM (multi-chip module) samples. Previous work has shown that the scanning SQUID microscope is capable of locating shorts in a C4 chip carrier and a ball grid array package, however the physical analysis was not performed to verify the (presumed) fail locations. In the present work, shorted areas in a chips-first MCM were located by SQUID microscopy and confirmed by mechanical cross-sectioning. When a short in a second MCM was found by SQUID microscopy and repaired with a laser, the power-to-ground resistance increased by more than a factor of 1000, bringing the part within specification. Techniques such as emission microscopy were unsuccessful in detecting the shorted current paths in these devices. Thus scanning SQUID microscopy is the only known method for locating and repairing defects in this product.

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来源期刊

2000 IEEE International Reliability Physics Symposium Proceedings. 38th Annual (Cat. No.00CH37059)

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