Laser-pulse propagation and interaction with low-temperature electron-hole plasmas in nanowire arrays

We present results from finite-difference time-domain simulations solving for the electric and magnetic fields of ultrashort laser pulses. These laser fields propagate through arrays of semiconductor quantum wires, in which they excite and interact with a low-temperature electron-hole plasma. These low-temperature plasmas are driven by ultrashort laser pulses, electron-hole scattering between all energy bands, and resistive forces for momentum relaxation due to Coulomb scattering and collisions with the lattice. The simulations allow us to study the correlation between the localized plasma response of quantum wires and the spatial-temporal features and phases of the scattered laser pulses. Presented results showing the influence of these effects on the quantum wire polarization and current density may inform studies of optical high-harmonic generation, while the results on plasma mobility can further our understanding of ultrafast electronics.