# Formation of Cu6Sn5 phase by cold homogenization in nanocrystalline   Cu-Sn bilayers at room temperature

**Authors:** H. Zaka, S.S. Shenouda, S.S. Fouad, M. Medhat, G.L. Katona, A. Csik,, G.A. Langer, D.L. Beke

arXiv: 1701.01596 · 2017-01-09

## TL;DR

This study demonstrates that nanocrystalline Cu-Sn bilayers can rapidly form a homogeneous Cu6Sn5 phase at room temperature through solid state reactions, enabling low-temperature soldering processes.

## Contribution

It reveals a novel room-temperature formation of Cu6Sn5 via cold homogenization in nanocrystalline Cu-Sn bilayers, without forming Cu3Sn, and provides detailed growth kinetics.

## Key findings

- Rapid formation of Cu6Sn5 layer within hours at room temperature
- Growth rate coefficient of 2.3 x 10^-15 cm^2/s for the reaction layer
- Solid state reaction driven by grain boundary diffusion

## Abstract

Solid state reaction between nanocrystalline Cu and Sn films was investigated at room temperature by depth profiling with secondary neutral mass spectrometry and by X-ray diffraction. A rapid diffusion intermixing was observed leading to the formation of homogeneous Cu 6Sn5 layer. There is no indication of the appearance of the Cu3Sn phase. This offers a way for solid phase soldering at low temperatures, i.e. to produce homogeneous Cu6Sn5 intermediate layer of several tens of nanometers during reasonable time (in the order of hours or less). From the detailed analysis of the growth of the planar reaction layer, formed at the initial interface in Sn(100 nm)/Cu(50 nm) system, the value of the parabolic growth rate coefficient at room temperature is 2.3 x 10-15 cm2/s. In addition, the overall increase of the composition near to the substrate inside the Cu film was interpreted by grain boundary diffusion induced solid state reaction: the new phase formed along the grain boundaries and grew perpendicular to the boundary planes. From the initial slope of the composition versus time function, the interface velocity during this reaction was estimated to be about 0.5 nm/h.

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Source: https://tomesphere.com/paper/1701.01596