Author_Institution :
Components Res., Intel Corp., Hillsboro, OR, USA
Abstract :
The quantum-well (QW) heterojunction bipolar transistor (HBT) laser [the transistor laser (TL)], inherently a fast switching device, operates by transporting small minority base charge densities ~1016 cm-3 over nanoscale base thickness ( 900 A) in picoseconds. The base QW acts as an optical “collector,” in addition to the usual electrical collector, that selects out “fast” recombining carriers, resulting in a short lifetime (~ 29 ps) and higher differential laser gains. Charge and current continuity, together with the boundary conditions imposed by both collectors of the TL lead to a new charge control model, “unpinning” of population inversion beyond lasing threshold, quasi-Fermi level discontinuity across base QW, and a new equivalent circuit model requiring an extension to Kirchhoff´s law. With the TL, the HBT becomes more than just a charge control device, but also a photon storage and switching device. The TL, owing to fast recombination speed, its unique three-terminal configuration, and the complementary nature of its optical and electrical collector output signals, enables resonance-free base current and collector voltage modulations, and compact realization of electro-optical applications such as nonlinear signal mixing, frequency multiplication, negative feedback, and optoelectronic logic gates.
Keywords :
Fermi level; carrier lifetime; equivalent circuits; heterojunction bipolar transistors; high-speed optical techniques; minority carriers; optical modulation; population inversion; quantum well lasers; HBT laser; Kirchhoff law; boundary conditions; carrier recombination; charge continuity; charge control model; collector voltage modulation; current continuity; differential laser gains; electrical collector output signal; electrooptical applications; equivalent circuit model; frequency multiplication; lasing threshold; minority base charge densities; nanoscale base thickness; negative feedback; nonlinear signal mixing; optical collector output signal; optoelectronic logic gates; photon storage; population inversion; quantum-well heterojunction bipolar transistor laser; quasiFermi level discontinuity; resonance-free base current modulation; switching device; three-terminal configuration; Charge carrier lifetime; Heterojunction bipolar transistors; Laser theory; Light emitting diodes; Quantum well devices; Radiative recombination; Resonance; Transistors; Analog and logic optoelectronic circuits; carrier–photon dynamics; charge control; current and voltage modulation; dependent optical source; differential laser gain; equivalent circuit model; feedback linearization; frequency multiplication; heterojunction bipolar transistor (HBT); laser theory; light-emitting transistor (LET); optical switch; quantum transitions; quasi-fermi level discontinuity; resonance-free response; stimulated and spontaneous recombination; transistor laser (TL); tunnel junction (TJ) transistor laser;
