RELATIONSHIP BETWEEN COPPER CONCENTRATION AND STRESS DURING ELECTROMIGRATION IN AN A1(0.25 AT % CU) CONDUCTOR LINE

IF 16.8 1区生物学

Nature Structural &Molecular Biology Pub Date : 2003-03-04 DOI:10.1063/1.1539282

H. Kao, G. Cargill, F. Giuliani, C. Hu

引用次数: 7

Abstract

Synchrotron-based x-ray microbeam fluorescence and diffraction have been used for in situ measurements of Cu concentration and biaxial stress in a 200-μm-long, 10-μm-wide Al(0.25 at. % Cu) conductor line with 1.5-μm-thick SiO2 passivation during electromigration. Measurements over 48 h with T=300 °C and j=1.5×105 A/cm2 show that a stress gradient of 3 MPa/μm develops over the upstream 130 μm of line length where Cu concentration drops below 0.15 at. %, and a 10-μm-long void develops at the cathode end of the line, but little change in stress occurs over the downstream 70 μm of line length where Cu concentration remains above 0.15 at. %. These experimental results have been reproduced by a finite element model in which the downstream Cu transport is accompanied by a counter flow of Al in the upstream direction, and downstream Al motion is blocked where the local Cu concentration is above ∼0.15 at. %. Defect mediated coupling between Al and Cu diffusive flows, e.g., Cu–vacancy binding, is proposed as the ca...

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a1 (0.25 at % cu)导体线电迁移过程中铜浓度与应力的关系

基于同步加速器的x射线微束荧光和衍射用于200 μm长，10 μm宽的铝(0.25 at)中Cu浓度和双轴应力的原位测量。在电迁移过程中，用1.5 μm厚的SiO2钝化导体线。温度为300°C, j=1.5×105 A/cm2，温度为48 h时，在线长上游130 μm处出现了3 MPa/μm的应力梯度，Cu浓度降至0.15 at以下。%时，阴极端出现了一个10 μm长的空洞，但在线长下游70 μm处，Cu浓度保持在0.15以上，应力变化不大。这些实验结果已经被一个有限元模型再现，在这个模型中，下游的Cu输运伴随着上游方向的Al逆流，当局部Cu浓度高于0.15 at. %时，下游的Al运动被阻断。缺陷介导的Al和Cu扩散流之间的耦合，例如Cu -空位结合，被认为是最有效的方法。

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

Nature Structural &Molecular Biology 生物-生化与分子生物学

自引率

1.80%

发文量

160

期刊介绍： Nature Structural & Molecular Biology is a monthly journal that focuses on the functional and mechanistic understanding of how molecular components in a biological process work together. It serves as an integrated forum for structural and molecular studies. The journal places a strong emphasis on the functional and mechanistic understanding of how molecular components in a biological process work together. Some specific areas of interest include the structure and function of proteins, nucleic acids, and other macromolecules, DNA replication, repair and recombination, transcription, regulation of transcription and translation, protein folding, processing and degradation, signal transduction, and intracellular signaling.