Understanding the sintering and heat dissipation behaviours of Cu nanoparticles during low-temperature selective laser sintering process on flexible substrates

In this paper, a facile method was introduced to fabricate fine conductive patterns by low-temperature selective laser sintering of Cu nanoparticles. By virtue of a nanosecond-pulsed ultraviolet laser source, fine circuits with a thickness of similar to 8 mu m and a conductivity of 3-6.5 x 10(6) S m(-1) was successfully fabricated from Cu nanoparticle paste with a high metal content >80 wt.% on a flexible substrate at a wide scan rate range of 5-500 mm s(-1). The sintered circuits exhibited a special sandwich morphology, with fully melted features in the centre and thermally sintered neck-connected features on the edges. A twofold linear relationship between the width of thermally sintered region and the reciprocal of the laser scan rate was revealed, indicating a heat dissipation mode transition from metal layer dominated dissipation to substrate dominated dissipation with the decrease of the laser scan rate. Finite element simulations were carried out to study the evolutions of temperature field and heat dissipation with changing laser scan rate and power, and the results fitted well with experimental results. On this basis, a relational expression was further proposed to determine the optimal processing window for laser sintering of metal nanoparticle layers. Our method extends the producible thickness and improves the fabrication efficiency of laser-printed circuits with desirable conductivity. The findings of this study can provide a guidance for understanding and controlling the sintering and heat transfer process of printing methods with similar materials and techniques.

Automated summary

A facile method was introduced to fabricate fine conductive patterns by low-temperature selective laser sintering of Cu nanoparticles. The sintered circuits exhibited unique sandwich morphology and a twofold linear relationship between the width of thermally sintered region and the reciprocal of the laser scan rate was revealed. Finite element simulations were carried out to study the evolutions of temperature field and heat dissipation with changing laser scan rate and power, providing guidance for controlling the sintering and heat transfer process.