扩散阻挡层
材料科学
合金
阻挡层
扩散
互连
电阻率和电导率
电介质
双层
可靠性(半导体)
图层(电子)
电迁移
光电子学
复合材料
化学
电气工程
计算机科学
膜
热力学
功率(物理)
生物化学
物理
工程类
计算机网络
作者
Cheol Kim,Geosan Kang,Youngran Jung,Ji-Yong Kim,Gibaek Lee,Deokgi Hong,Yoongu Lee,Soon-Gyu Hwang,In‐Ho Jung,Young‐Chang Joo
标识
DOI:10.1038/s41598-022-16288-y
摘要
With recent rapid increases in Cu resistivity, RC delay has become an important issue again. Co, which has a low electron mean free path, is being studied as beyond Cu metal and is expected to minimize this increase in resistivity. However, extrinsic time-dependent dielectric breakdown has been reported for Co interconnects. Therefore, it is necessary to apply a diffusion barrier, such as the Ta/TaN system, to increase interconnect lifetimes. In addition, an ultrathin diffusion barrier should be formed to occupy as little area as possible. This study provides a thermodynamic design for a self-forming barrier that provides reliability with Co interconnects. Since Cr, Mn, Sn, and Zn dopants exhibited surface diffusion or interfacial stable phases, the model constituted an effective alloy design. In the Co-Cr alloy, Cr diffused into the dielectric interface and reacted with oxygen to provide a self-forming diffusion barrier comprising Cr2O3. In a breakdown voltage test, the Co-Cr alloy showed a breakdown voltage more than 200% higher than that of pure Co. The 1.2 nm ultrathin Cr2O3 self-forming barrier will replace the current bilayer barrier system and contribute greatly to lowering the RC delay. It will realize high-performance Co interconnects with robust reliability in the future.
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