论文信息 - Evaluation of thermal fatigue damage of 200-nm-thick Au interconnect lines

Evaluation of thermal fatigue damage of 200-nm-thick Au interconnect lines

Thermal fatigue properties of 200-nm-thick Au interconnects with a width of 2 lm were evaluated by applying alternating current. We found that the temperature distribution along the Au interconnect can be described by a simplified one-dimensional equation of heat conduction. The lifetime as a function of thermal cyclic strain range (De) for the narrow Au lines follows the conventional Coffin–Manson relationship when De 6 0.47%, while the number of cycles to failure extends to an engineering-defined high-cycle fatigue region.

Guang-Ping Zhang | Bao-Yan Zhang | M. Wang | C. S. Liu

[1] Robert R. Keller,et al. Thermal fatigue testing of thin metal films , 2004 .

[2] S. Suresh. Fatigue of materials , 1991 .

[3] O. Kraft,et al. Effect of film thickness and grain size on fatigue-induced dislocation structures in Cu thin films , 2003 .

[4] D. Read. Tension-Tension Fatigue of Copper Thin Films , 1996, Structural Analysis in Microelectronics and Fiber Optics.

[5] E. Arzt,et al. Length-scale-controlled fatigue mechanisms in thin copper films , 2006 .

[6] O. Kraft,et al. Size effects in the fatigue behavior of thin Ag films , 2003 .

[7] Milton Ohring,et al. Reliability and Failure of Electronic Materials and Devices, Second Edition , 1998 .

[8] Christine S. Hau-Riege,et al. An introduction to Cu electromigration , 2004, Microelectron. Reliab..

[9] O. Kraft,et al. High cycle fatigue of thin silver films investigated by dynamic microbeam deflection , 1999 .

[10] E. Arzt,et al. Fatigue behavior of polycrystalline thin copper films , 2002 .

[11] Oliver Kraft,et al. Cyclic deformation of polycrystalline Cu films , 2003 .

[12] Rolf Weil,et al. Low cycle fatigue of thin copper foils , 1996 .

[13] R. Mönig,et al. Thermal fatigue as a possible failure mechanism in copper interconnects , 2006 .