Soliton dynamics in the multiphoton plasma regime

TL;DR

This paper reports the first phase-resolved observations of femtosecond optical solitons in a semiconductor microchip, revealing complex photon-plasma interactions driven by multiphoton ionization at ultralow energies.

Contribution

It introduces the first experimental evidence of femtosecond solitons in a semiconductor microchip under multiphoton ionization, highlighting novel ultralow-power nonlinear photon-plasma dynamics.

Findings

Observation of free-electron-induced blue-shift at high carrier densities

Detection of soliton splitting dynamics on-chip

Suppression of soliton recurrence due to free-electron effects

Abstract

Solitary waves have consistently captured the imagination of scientists, ranging from fundamental breakthroughs in spectroscopy and metrology enabled by supercontinuum light, to gap solitons for dispersionless slow-light, and discrete spatial solitons in lattices, amongst others. Recent progress in strong-field atomic physics include impressive demonstrations of attosecond pulses and high-harmonic generation via photoionization of free-electrons in gases at extreme intensities of 1014 Wcm2. Here we report the first phase-resolved observations of femtosecond optical solitons in a semiconductor microchip, with multiphoton ionization at picojoule energies and 1010 Wcm2 intensities. The dramatic nonlinearity leads to picojoule observations of free-electron-induced blue-shift at 1016 cm3 carrier densities and self-chirped femtosecond soliton acceleration. Furthermore, we evidence the time-gated dynamics of soliton splitting on-chip, and the suppression of soliton recurrence due to fast free-electron dynamics. These observations in the highly dispersive slow-light media reveal a rich set of physics governing ultralow-power nonlinear photon-plasma dynamics.