Robust TiN HM process to overcome under etch issue for SAV scheme on 14nm node

2015 IEEE International Interconnect Technology Conference and 2015 IEEE Materials for Advanced Metallization Conference (IITC/MAM) Pub Date : 2015-05-18 DOI:10.1109/IITC-MAM.2015.7325602

Tzu-Hao Fu, Y. Ke, Shi-Chun Tsai, Chun-Ling Lin, Kuo-Wei Chen, M. Huang, Gary Cho, San-Fu Lin, Ting-Jun Wang, A. Cheng

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引用次数: 2

Abstract

For advance node such as 14nm technology and beyond, back end of line interconnect has implemented self-aligned via (SAV) schemes for better via-metal short process window [1]. A TiN metal hard mask (MHM) is used for the trench pattern definition, after which via lithography and partial via (PV) etch is performed where the TiN was opened. The via etch condition has very good selectivity so that via is formed in a self-aligned fashion by TiN HM [2]. It is indeed to have significant benefit of via to metal short [3]. However, one of the trade off in SAV scheme is the via under etch that whether or not via can well land on an opened oxide area during PV etch. To define the contact area between via resist hole and opened HM oxide as an effective area for via to open successfully. “Fig. 1” shows the effective area change during process variation due to Via alignment, Via photo resist CD variation (Via ADICD) and post hard mask etch CD variation (AMICD). “Fig. 2” shows the mechanism of this under etch failure mode and typical TEM image from 64nm metal pitch test vehicle. In this work, we try to enlarge the process window by an aggressive AMICD targeting in combining with a higher density TiN material to maintain profile.

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稳健的TiN HM工艺克服了14nm节点SAV方案的腐蚀问题

对于先进的节点，如14nm及以上的技术，后端线互连已经实现了自对准通孔(SAV)方案，以获得更好的通孔金属短工艺窗口[1]。TiN金属硬掩膜(MHM)用于沟槽图案定义，然后通过光刻和部分通孔(PV)蚀刻在TiN打开的地方进行。通过蚀刻条件具有很好的选择性，使得通过形成自对准方式的TiN HM[2]。确实是通过对金属短[3]有显著的好处。然而，SAV方案中的一个权衡是蚀刻下的通孔，在PV蚀刻期间，通孔是否能很好地落在开放的氧化区。确定通孔电阻孔与打开的HM氧化物之间的接触面积，作为通孔成功打开的有效面积。“图1”显示了在工艺变化过程中由于Via对准、Via光抗蚀CD变化(Via ADICD)和后硬掩模蚀刻CD变化(AMICD)而导致的有效面积变化。如图2所示为腐蚀失效模式下的机理，以及64nm金属间距测试车的典型TEM图像。在这项工作中，我们试图通过积极的AMICD瞄准结合更高密度的TiN材料来扩大工艺窗口，以保持轮廓。

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

2015 IEEE International Interconnect Technology Conference and 2015 IEEE Materials for Advanced Metallization Conference (IITC/MAM)

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