Impact of impurities on leakage current induced by High-Energy Density Pulsed Laser Annealing in Si diodes

TL;DR

This study investigates how high-energy pulsed laser annealing affects leakage current in silicon diodes, revealing that impurity incorporation and defect formation at high energy densities increase leakage through trap centers.

Contribution

It provides new insights into impurity effects and defect dynamics during high-energy laser annealing, highlighting their impact on leakage current in silicon diodes.

Findings

Higher laser energy densities increase vacancy concentrations.

Multiple pulses promote defect diffusion and impurity incorporation.

Trap centers formed degrade diode leakage current.

Abstract

For semiconductor device fabrication, Pulsed Laser Annealing (PLA) offers significant advantages over conventional thermal processes. Notably, it can provide ultrafast (~ns) and high temperature profiles ($>1000^\circ$C). When the maximum temperature exceeds the melting point, a solid-liquid phase transition is observed, immediately followed by rapid recrystallization. This unique annealing mechanism gives raises questions about dopant diffusion and residual defects, in not only in the recrystallized region, but also just below it. As power devices require micrometer-sized junctions, high laser energy densities are needed, which were proved to promote the incorporation of complex impurities from the surface and the creation of defects at the liquid/solid interface. This paper reports on the impact of laser annealing at high energy densities (up to 8.0 J/cm$^2$) on the leakage current, using Schottky and PN diodes, and DLTS measurements. Various laser annealing conditions were used: energy densities between 1.7 and 8.0 J/cm$^2$ with 1 to 10 pulses. Our results suggest that the liquid and solid solubility of vacancies in silicon are fixed by the maximum temperature reached, so to the energy density. Increasing the number of laser pulses allows, not only to reach this maximum vacancy concentration but also to promote their diffusion towards the surface. Concomitantly, the in-diffusion of complex impurities inside the melted region allows the coupling between both defect types to create trap centers, responsible for the degradation of the leakage current.