Title :
Ultrafast cross-well carrier transport in a strained multiple-quantum-well InGaAs-GaAs p-i-n modulator
Author :
Wang, Haisheng ; Effenberger, Frank J. ; LiKamWa, P. ; Miller, Alan
Author_Institution :
Photonic Center, US Air Force Rome Lab., NY, USA
fDate :
2/1/1997 12:00:00 AM
Abstract :
We report ultrafast optical pump-probe measurements of cross-well carrier transport in a strained multiple-quantum-well InGaAs-GaAs p-i-n modulator. The transmission response of the modulator is recorded over a range of reverse bias values, wavelengths, and power levels, producing several qualitatively different response types. A simplified physical model is developed to describe this behavior. This model includes transmission changes due to exciton saturation and excitonic field screening, carrier emission from the quantum wells and drift through the intrinsic region, and voltage diffusion across the p- and n-doped electrodes. This model agrees well with the experimental data
Keywords :
III-V semiconductors; carrier mobility; electro-optical modulation; gallium arsenide; high-speed optical techniques; indium compounds; p-i-n diodes; semiconductor device models; semiconductor device testing; semiconductor quantum wells; InGaAs-GaAs; InGaAs-GaAs p-i-n modulator; carrier emission; exciton saturation; excitonic field screening; intrinsic region; n-doped electrodes; p-doped electrodes; power levels; qualitatively different response types; reverse bias values; simplified physical model; strained multiple-quantum-well InGaAs-GaAs p-i-n modulator; transmission changes; transmission response; ultrafast cross-well carrier transport; ultrafast optical pump-probe measurements; voltage diffusion; Excitons; Optical modulation; Optical pumping; Optical recording; Optical saturation; PIN photodiodes; Quantum well devices; Ultrafast optics; Voltage; Wavelength measurement;
Journal_Title :
Quantum Electronics, IEEE Journal of
