Having shown in Chap. 1 that the future development of microelectronics will lead to more and more electromigration problems, let us now investigate in detail the actual low-level migration processes. A solid grounding in the physics of electro-migration (EM) and its specific effects on the interconnect will give us the knowledge to establish effective mitigation methods during the design of integrated circuits (ICs). We first explain the physical causes of EM (Sect. 2.1) and then present options to quantify the EM process (Sect. 2.2), which enable us to effectively characterize key aspects of the process and its effects. In Sect. 2.3, we introduce EM-influencing factors arising from the specific circuit technology, the environment, and the design. We then investigate detailed EM mechanisms with regard to circuit materials, frequencies, and mechanical stresses (Sect. 2.4). Since EM is closely related to other migration processes, such as thermal and stress migration that also occur in the conductors of electronic circuits, we examine their interdependencies (Sect. 2.5). IC designers must be especially aware of thermal and stress migration; both are introduced and described in their interaction with EM. Finally, Sect. 2.6 outlines the principles of a migration analysis through simulation. This honors the importance of finite element modeling (using the finite element method, FEM) in electromigration analysis and enables the reader to develop and apply similar modeling and simulation techniques.
CITATION STYLE
Lienig, J., & Thiele, M. (2018). Fundamentals of Electromigration. In Fundamentals of Electromigration-Aware Integrated Circuit Design (pp. 13–60). Springer International Publishing. https://doi.org/10.1007/978-3-319-73558-0_2
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