Title :
Interdiffusion of Cu-Sn system with Ni ultra-thin buffer layer and material analysis of IMC growth mechanism
Author :
Cheng-Han Fan ; Yao-Jen Chang ; Yi-Chia Chou ; Kuan-Neng Chen
Author_Institution :
Dept. of Electrophys., Nat. Chiao Tung Univ., Hsinchu, Taiwan
Abstract :
In this paper, Ni ultra-thin diffusion buffer layer between Cu/Sn is inserted to suppress the IMC (η-phase) inter-diffusion reaction. We analogy the bonding condition by using single side Cu/Ni buffer layer/Sn structure. The inter-diffusion behaviors and IMC growth are investigated under the same thermal budget of bonding temperature during the heating step. Cu/Sn IMC formation behavior with Ni buffer layer is summarized by the SEM inspection. In the results of different Ni buffer layers (tNi = 0, 50, 100, 150 Å) and thermal durations (0 to 60 sec), Ni buffer layer insertion can effectively reduce Cu/Sn IMC thickness. In addition, rapid growth of ~1.5 μm Cu/Sn IMC thickness at 250°C for only 10 sec is discovered. As results, 100 Å Ni buffer layer is necessary to apply as the Cu/Sn system enters the submicron pad bonding interconnects.
Keywords :
chemical interdiffusion; copper alloys; integrated circuit bonding; nickel; scanning electron microscopy; tin alloys; wafer-scale integration; η-phase interdiffusion reaction; Cu-Sn; Cu-Sn IMC formation behavior; IMC growth; IMC interdiffusion reaction; Ni; Ni ultra-thin diffusion buffer layer; SEM inspection; bonding condition; bonding temperature; heating step; single side Cu-Ni buffer layer-Sn structure; submicron pad bonding interconnects; temperature 250 C; thermal durations; time 0 s to 60 s; Bonding; Buffer layers; Compounds; Intermetallic; Nickel; Tin;
Conference_Titel :
Microsystems, Packaging, Assembly and Circuits Technology Conference (IMPACT), 2014 9th International
DOI :
10.1109/IMPACT.2014.7048448
