Title :
Mechanical Construction of Semiconductor Band Gaps
Author :
Makowski, Jan D. ; Anderson, Brady D. ; Chang, Wing S. ; Saarinen, Mika J. ; Palmstrøm, Christopher J. ; Talghader, Joseph J.
Author_Institution :
Robert Bosch GmbH, Reutingen, Germany
Abstract :
Mechanical position is used to control the wavelength of light emission of semiconductor heterostructures. The heterostructures are coupled across a gap that varies with position to tune electron states in much the same manner that optical cavities can be coupled across a tunable reflectivity mirror to control photon states. In the experiments, a SixN/InP cantilever containing an InGaAs surface well collapses over another InGaAs quantum well. The spacing between the wells varies along the cantilever, such that the heterostructure band gap is determined by the mechanical bending of the cantilever. Photoluminescence measurements of the coupled 200°A surface wells show a wavelength shift of up to 22 nm. Associated theory shows that mechanical quantum coupling enables interband or intersubband devices with unprecedented spectral tuning ranges for gain or absorption.
Keywords :
III-V semiconductors; cantilevers; indium compounds; interface states; light absorption; micro-optics; photoluminescence; photonic band gap; quantum wells; InGaAs; SixN-InP; cantilever; electron states; light emission wavelength; mechanical bending; mechanical construction; mechanical quantum coupling; optical absorption; optical gain; photoluminescence measurement; quantum well; semiconductor band gaps; semiconductor heterostructure; spectral tuning; surface well; Electron optics; Indium gallium arsenide; Lighting control; Mirrors; Optical control; Optical coupling; Optical surface waves; Photonic band gap; Reflectivity; Stimulated emission; Microelectromechanical devices; photoluminescence (PL); quantum effect semiconductor devices; quantum well devices;
Journal_Title :
Quantum Electronics, IEEE Journal of
DOI :
10.1109/JQE.2010.2047245
