Title :
Tunneling-injection quantum-dot laser: ultrahigh temperature stability
Author :
Asryan, Levon V. ; Luryi, Serge
Author_Institution :
State Univ. of New York, Stony Brook, NY, USA
Abstract :
We propose a genuinely temperature-insensitive quantum dot (QD) laser. Our approach is based on direct injection of carriers into the QDs, resulting in a strong depletion of minority carriers in the regions outside the QDs. Recombination in these regions, which is the dominant source of the temperature dependence, is thereby suppressed, raising the characteristic temperature T0 above 1500 K. Still further enhancement of T0 results from the resonant nature of tunneling injection, which reduces the inhomogeneous line broadening by selectively cutting off the nonlasing QDs
Keywords :
laser stability; laser theory; minority carriers; quantum well lasers; resonant tunnelling; semiconductor quantum dots; spectral line broadening; 1500 K; characteristic temperature; direct carrier injection; inhomogeneous line broadening; minority carrier strong depletion; nonlasing QD; recombination; temperature dependence; temperature-insensitive quantum dot laser; tunneling injection resonant nature; tunneling-injection quantum-dot laser; ultrahigh temperature stability; Laser stability; Quantum dot lasers; Quantum well lasers; Radiative recombination; Semiconductor lasers; Spontaneous emission; Temperature dependence; Temperature sensors; Threshold current; Tunneling;
Journal_Title :
Quantum Electronics, IEEE Journal of
