Mechanisms for Fatigue of Micron-Scale Silicon Structural Films

Although bulk silicon is not susceptible to fatigue, micron‐scale silicon is. Several mechanisms have been proposed to explain this surprising behavior although the issue remains contentious. Here we review published fatigue results for micron‐scale thin silicon films and find that in general they display similar trends, in that lower cyclic stresses result in larger number of cycles to failure in stress‐lifetime data. We further show that one of two classes of mechanisms is invariably proposed to explain the phenomenon. The first class attributes fatigue to a surface effect caused by subcritical (stable) cracking in the silicon‐oxide layer, e.g., reaction‐layer fatigue; the second class proposes that subcritical cracking in the silicon itself is the cause of fatigue in Si films. It is our contention that results to date from single and polycrystalline silicon fatigue studies provide no convincing experimental evidence to support subcritical cracking in the silicon. Conversely, the reaction‐layer mechanism is consistent with existing experimental results, and moreover provides a rational explanation for the marked difference between the fatigue behavior of bulk and micron‐scale silicon. Although bulk silicon is not susceptible to fatigue, micron‐scale silicon is. Several mechanisms have been proposed to explain this surprising behavior although the issue remains contentious. This review describes fatigue results for micron‐scale thin silicon films from several different studies and concludes that a reaction‐layer fatigue mechanism provides the most conclusive explanation for all the presented data and for the marked difference in fatigue behavior of bulk and micron‐scale silicon.