Non-steady state transport of charge carriers. An approach based on invariant embedding method

STRAUBE, B.; FERREYRA, J.; FIGUEROA, C.; BRIDOUX, G.; HELUANI, S.P.; VILLAFUERTE, M.; VEGA, N.C.

JOURNAL OF APPLIED PHYSICS

AMER INST PHYSICS

Año: 2020 vol. 127 p. 45703 - 45711

0021-8979

In this work, we report on a model that describes the microscopic electrical transport as a transmission problem using the invariant embedding technique. Analytical expressions for the transport coefficients under non-steady-state conditions are derived allowing us to calculate carrier concentration and time-dependent conductivity. Employing measurable magnitudes, our theoretical results allow us to determine defect concentrations, carrier generation rates, cross sections of recombination, and capture by traps. This model can be employed to study the conduction processes of semiconductors and test their band and defect structure. In particular, time-dependent photoconductivity measurements of a ZnO microwire have been well fitted using our model indicating a relevant role of intrinsic point defects in this material.