Title :
Pseudomorphic bipolar quantum resonant-tunneling transistor
Author :
Seabaugh, Alan C. ; Frensley, William R. ; Randall, John N. ; Reed, Mark A. ; Farrington, Dewey L. ; Matyi, Richard J.
Author_Institution :
Texas Instrum. Inc., Dallas, TX, USA
fDate :
10/1/1989 12:00:00 AM
Abstract :
A bipolar tunneling transistor in which ohmic contact is made to the strained p+ InGaAs quantum well of a double-barrier resonant-tunneling structure is discussed. The heterojunction transistor consists of an n-GaAs emitter and collector, undoped AlGaAs tunnel barriers, and a pseudomorphic p+ InGaAs quantum-well base. By making ohmic contact to the p-type quantum well, the hole density in the quantum-well base is used to modulate the base potential relative to the emitter and collector terminals. With control of the quantum-well potential, the tunneling current can be modulated by application of a base-to-emitter potential. The authors detail the physical and electrical characteristics of the device. It is found that the base-emitter voltages required to bias the transistor into resonance are well predicted by a self-consistent calculation of the electrostatic potential
Keywords :
III-V semiconductors; aluminium compounds; carrier density; electric potential; gallium arsenide; heterojunction bipolar transistors; hot electron transistors; indium compounds; AlGaAs tunnel barriers; InGaAs quantum well; InGaAs-AlGaAs-GaAs; base potential; base-emitter voltages; base-to-emitter potential; bipolar tunneling transistor; double-barrier resonant-tunneling structure; electrical characteristics; heterojunction transistor; hole density; ohmic contact; quantum-well potential; self-consistent calculation; tunneling current; Electric variables; Electrostatics; Heterojunctions; Indium gallium arsenide; Ohmic contacts; Quantum well devices; Quantum wells; Resonance; Resonant tunneling devices; Voltage;
Journal_Title :
Electron Devices, IEEE Transactions on
