Laser backside contact annealing of SiC power devices: A prerequisite for SiC thin wafer technology

2013 25th International Symposium on Power Semiconductor Devices & IC's (ISPSD) Pub Date : 2013-05-26 DOI:10.1109/ISPSD.2013.6694396

R. Rupp, R. Kern, R. Gerlach

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引用次数: 19

Abstract

We developed a new backside contact formation process for SiC power devices based on pulsed laser annealing providing an ohmic contact with lower contact resistance and better adhesion properties than contacts formed by conventional rapid thermal annealing. This process does not add any significant thermal budget to the wafer front side and therefore allows a “short thin wafer” process, means completing the wafer front side including the imide process before thinning and backside metallization. By that means both the risk of wafer breakage and substrate contribution to the total device resistance are minimized at the same time. This is clearly shown by comparing 650V SiC Schottky diodes with identical device structure but different total chip thickness (360 vs 110 μm). Besides the advantage in differential resistance also other properties like heat flux through the device (Rth), non destructive surge current density (I2t) and reliability are improved by the SiC thin wafer technology enabled by the laser backside contact annealing.

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SiC功率器件的激光背面接触退火:SiC薄晶圆技术的先决条件

我们开发了一种基于脉冲激光退火的SiC功率器件背面触点形成新工艺，提供了比传统快速热退火形成的触点具有更低接触电阻和更好粘附性能的欧姆触点。该工艺不会给晶圆正面增加任何显著的热预算，因此允许“短薄晶圆”工艺，这意味着在变薄和背面金属化之前完成晶圆正面，包括亚胺工艺。通过这种方法，晶圆破裂的风险和基板对器件总电阻的贡献同时被最小化。通过比较具有相同器件结构但总芯片厚度(360 vs 110 μm)不同的650V SiC肖特基二极管，可以清楚地表明这一点。除了在差分电阻方面的优势外，通过激光背面接触退火实现的SiC薄晶片技术还提高了其他性能，如通过器件的热流密度(Rth)，非破坏性浪涌电流密度(I2t)和可靠性。

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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2013 25th International Symposium on Power Semiconductor Devices & IC's (ISPSD)

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