Power nano- and picosecond optoelectronic switches based on high-voltage silicon structures with p-n-junctions. I. Physics of switching process

TL;DR

This paper presents the first numerical simulation of high-voltage silicon optoelectronic switches triggered by picosecond laser pulses, revealing empirical relationships between control parameters and switching behavior.

Contribution

It introduces novel numerical simulations of high-voltage silicon switches triggered by picosecond laser pulses and derives empirical and analytical relationships for their switching processes.

Findings

Established empirical relationships between control pulse energy, absorption coefficient, and switch parameters.

Derived approximate analytical formulas matching simulation results.

Identified differences in switching behavior among various silicon switch types at long voltage pulse durations.

Abstract

Numerical simulation of switching process of high-voltage silicon photodiodes, phototransistors and photothyristors those triggered-on homogeneously over the area by picosecond laser pulses, has been performed for the first time. The analysis of results allowed to obtain "empirical" relationship between key parameters of switches (energy of control pulses, a radiation absorption coefficient, the area of structures) and parameters those characterizing the switching process in a circuit with the resistive load. For some of these relationship the approximate analytical formulas which seem to be quite adequate to the simulation results has been deduced. It is noted that distinctions between switching processes in structures of the three different types become apparent only at long duration of voltage pulses at a final stage when the blocking capability of photodiodes and phototransistors is recovered.