Ge-friendly gate stacks: Initial property and long-term reliability

IF 2.7 Q2 PHYSICS, CONDENSED MATTER Micro and Nanostructures Pub Date : 2024-08-21 DOI:10.1016/j.micrna.2024.207958

Xiaoyu Tang, Rongjia Zhu, Yujie Liu, Zhezhe Han

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Abstract

This work presents specific exploration on the novel gate stack strategies for the intriguing Ge p-MOSFET, where high pressure oxidation (HPO) process is utilized for sufficient oxidation and thus fewer oxygen vacancies, while yttrium doping is developed to strengthen the dielectric bonding for higher ruggedness. Superior gate controllability and stability have been achieved correspondingly, where then detailed comparison on the gate dielectric reliability is conducted. The HPO based GeO₂ gate stack exhibits larger susceptibility to the gate bias stress, and could even breakdown under negative bias, which has been attributed to the local bond breakage that facilitates the irreversible network change. The yttrium-doped GeO₂, on the other hand, presents impressive ruggedness against gate bias stress. Based on detailed bond breakage analysis, cation-doping in GeO₂ is suggested to be effective in enhancing the bond rigidness, promising for a wider safe operation range for the gate bias in Ge MOSFET.

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Ge-friendly 栅极堆栈：初始特性和长期可靠性

本研究对引人入胜的 Ge p-MOSFET 的新型栅极堆叠策略进行了具体探索，其中高压氧化（HPO）工艺可实现充分氧化，从而减少氧空位，而掺钇工艺则可加强介电结合，提高坚固性。栅极的可控性和稳定性也相应得到了提高，随后对栅极介电可靠性进行了详细比较。基于 HPO 的 GeO2 栅极堆栈对栅极偏压应力表现出更大的敏感性，甚至会在负偏压下击穿，这归因于局部键的断裂促进了不可逆的网络变化。另一方面，掺钇的 GeO2 对栅极偏压应力的耐受性令人印象深刻。根据详细的键断裂分析，GeO2 中的阳离子掺杂可有效增强键的刚性，从而有望扩大 Ge MOSFET 栅极偏压的安全工作范围。

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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来源期刊

Micro and Nanostructures

CiteScore

6.50

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0.00%

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