TY - JOUR

T1 - Investigations on the mechanism of microweld changes during ultrasonic wire bonding by molecular dynamics simulation

AU - Long, Yangyang

AU - He, Bo

AU - Cui, Weizhe

AU - Ji, Yuhang

AU - Zhuang, Xiaoying

AU - Twiefel, Jens

N1 - Funding information: The financial support from DFG ( Deutsche Forschungsgemeinschaft ) program ( TW75/8-1|WA564/40-1 ) is gratefully acknowledged. The publication of this article was funded by the Open Access Publishing Fund of Leibniz Universität Hannover .

PY - 2020/4/5

Y1 - 2020/4/5

N2 - Despite the wide and long-term applications of ultrasonic (US) wire bonding and other US metal joining technologies, the mechanism of microweld changes during the bonding process, including formation, deformation and breakage, is rarely known as it is very difficult to be investigated by experiments. In this work, this mechanism under different surface topographies and displacement patterns is studied by molecular dynamics simulation. It is found that microwelds can be formed or broken instantly. Due to the relative motion between the local wire part and the local substrate part, microwelds can be largely deformed or even broken. The impacts of material, surface topography, approaching distance and vibration amplitude on the microweld changes are investigated via the quantification of the shear stress and the equivalent bonded area. It is shown that these four factors significantly influence the final connection and the interface structure. The analysis of the scale influence on the microweld changes shows that the simulation results at a small-scale are able to represent those at a large-scale which is close to the range of the commonly used surface roughness. This deeper understanding on the microweld changes leads to a better control strategy and an enhancement of the bonding process.

AB - Despite the wide and long-term applications of ultrasonic (US) wire bonding and other US metal joining technologies, the mechanism of microweld changes during the bonding process, including formation, deformation and breakage, is rarely known as it is very difficult to be investigated by experiments. In this work, this mechanism under different surface topographies and displacement patterns is studied by molecular dynamics simulation. It is found that microwelds can be formed or broken instantly. Due to the relative motion between the local wire part and the local substrate part, microwelds can be largely deformed or even broken. The impacts of material, surface topography, approaching distance and vibration amplitude on the microweld changes are investigated via the quantification of the shear stress and the equivalent bonded area. It is shown that these four factors significantly influence the final connection and the interface structure. The analysis of the scale influence on the microweld changes shows that the simulation results at a small-scale are able to represent those at a large-scale which is close to the range of the commonly used surface roughness. This deeper understanding on the microweld changes leads to a better control strategy and an enhancement of the bonding process.

KW - Bonding mechanism

KW - Microweld formation & breakage

KW - Molecular dynamics simulation

KW - Ultrasonic wire bonding

UR - http://www.scopus.com/inward/record.url?scp=85083528841&partnerID=8YFLogxK

U2 - 10.1016/j.matdes.2020.108718

DO - 10.1016/j.matdes.2020.108718

M3 - Article

AN - SCOPUS:85083528841

VL - 192

JO - Materials and design

JF - Materials and design

SN - 0264-1275

M1 - 108718

ER -