Photon-assisted breakdown, negative resistance, and switching in a quantum-well transistor laser

James, A.; Walter, G.; Feng, Milton; Holonyak, N.

doi:10.1063/1.2721364

Cited by 15 publications

(9 citation statements)

References 9 publications

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“…A similar breakdown in I C has previously been observed on npn-type T-VCSELs by Wu et al [2,4], who attributed it to a photon reabsorption process (Franz-Keldysh effect) in the base-collector junction that adds carriers to I C and also acts as a source of resupply of majority carriers to the base [4,9]. However, Franz-Keldysh absorption would here not be expected to increase beyond the breakdown in I C (at I B =I B,BD ) since any further increase in I B (corresponding to an increase in V EB and thereby a decrease in V BC =V EC -V EB ) will decrease rather than increase the band bending in the base-collector junction.…”

Section: Resultsmentioning

confidence: 66%

Performance Optimization of GaAs-Based Vertical-Cavity Surface-Emitting Transistor-Lasers

Reuterskiöld-Hedlund

et al. 2015

IEEE Photon. Technol. Lett.

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Abstract-We report on the optimization of pnp-type verticalcavity surface-emitting transistor-lasers based on the fusion between an AlGaAs/GaAs heterojunction bipolar transistor and an InGaAs/GaAs VCSEL using an epitaxial regrowth process. It is shown how a proper design of the base region can extend the transistor active range of operation well beyond lasing threshold, thereby resulting in typical transistor laser operational characteristics including mW-range output power, mA-range base threshold current, record-low power dissipation under laser operation, and continuous-wave operation up to at least 60°C. A pronounced breakdown in the collector current characteristics in the limit of high base current and/or emitter-collector voltage accompanied by a quenching of the optical output power is interpreted as being related to quantum well band-filling.

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Section: Resultsmentioning

confidence: 66%

Performance Optimization of GaAs-Based Vertical-Cavity Surface-Emitting Transistor-Lasers

Reuterskiöld-Hedlund

et al. 2015

IEEE Photon. Technol. Lett.

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“…As a result, the accumulated carriers there impede the successive photon absorption because of the Pauli exclusion principle. The phenomenon of saturation in α FK may be modeled as α FK (N p , E) = α FK0 (E) 1 + ε FK N p (5) where N p is the photon density, ε FK is an absorption suppression coefficient for the FK absorption, and E is the electrical field applied to the junction. The calculations of L-I and L-IV curves with ε FK = 3 × 10 −15 cm −3 are presented in Figs.…”

Section: Effective Internal Lossmentioning

confidence: 99%

“…With quantum wells (QWs) incorporated into the base regions of heterojunction bipolar transistors and with an improved optical confinement in the active regions, the buildup of the photon number and therefore lasing condition are achievable. The TL invented by Feng and Holonyak Jr. in 2004 demonstrated superiority in various functionalities such as the capability of nonlinear mixing [2], frequency multiplication [3], [4], negative resistance [5], photon-assisted switching [6], resonance-free operation with a modulation bandwidth of 20 GHz [7], and simultaneous electrical and optical open-eye signals at a 40 Gb/s data rate [8]. Previous results of the TL mainly focused on the unique current-voltage (I-V) and light-versus-current-voltage (L-IV) characteristics and high-speed performance.…”

Section: Introductionmentioning

confidence: 99%

Analysis of Tunable Internal Loss Caused by Franz–Keldysh Absorption in Transistor Lasers

Wang

Huang

Cheng

et al. 2015

IEEE J. Select. Topics Quantum Electron.

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The Franz-Keldysh (FK) absorption at the basecollector junction of a transistor laser (TL) is inevitable because of the reverse bias therein. The bias condition, thus, plays a crucial role in the determination of internal loss of TLs. In this study, effects from various facet coatings of edge-emitting TLs on the internal loss (α int ), which is influenced by the FK absorption, are investigated. Experimental analyses on the electrical and optical characteristics of these TLs at various temperatures are presented. The α int of different coated devices at various bias voltages are then extracted from their light-versus-current curves. We demonstrate that the internal loss resulted from the FK absorption is bias dependent, and therefore tunable. By contrast, the intense field inside the cavity with highly reflective coatings on both facets may saturate the FK absorption and make it less bias controllable. Index Terms-Transistor laser, Franz-Keldysh absorption, laser internal loss.1077-260X

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“…These layers are followed by a 557 Å n-type subcollector layer, a 120 Å In 0.49 Ga 0.51 P etch stop layer, and a 2871 Å undoped GaAs collector layer. The active layer design consists of a 1358 Å average p-doped 3 Â 10 19 is completed with the growth of a 511 Å n-type In 0.49 Ga 0.51 P wide-gap emitter layer, the upper cladding layers (the same as the bottom ones), and a 2000 Å heavily doped n-type GaAs contact layer. The HBT structure is identical to the LET structure except for the insertion of two QWs in the base region.…”

Section: Investigation Of Effective Base Transit Time and Current Gaimentioning

confidence: 99%

“…When V CE increases from 1.5 to 2.5 V at constant base current I B , the conventional HBT shows a decrease of the collector current (I C ), i.e., current gain drops, which is usually seen due to high power dissipation. However, the LET exhibits the reverse trend due to the photon-assisted tunneling (Franz-Keldysh absorption), 19 where the photongenerated holes are re-supplied to the base region while electrons are injected to the collector region, causing I C increases with V CE .…”

Section: Investigation Of Effective Base Transit Time and Current Gaimentioning

confidence: 99%

Investigation of effective base transit time and current gain modulation of light-emitting transistors under different ambient temperatures

Yang

Wang

et al. 2014

Applied Physics Letters

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In this report, the modulation of current gain of InGaP/GaAs light-emitting transistors under different ambient temperatures are measured and analyzed using thermionic emission model of quantum well embedded in the transistor base region. Minority carriers captured by quantum wells gain more energy at high temperatures and escape from quantum wells resulting in an increase of current gain and lower optical output, resulting in different I-V characteristics from conventional heterojunction bipolar transistors. The effect of the smaller thermionic lifetime thus reduces the effective base transit time of transistors at high temperatures. The unique current gain enhancement of 27.61% is achieved when operation temperature increase from 28 to 85 °C.

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Photon-assisted breakdown, negative resistance, and switching in a quantum-well transistor laser

Cited by 15 publications

References 9 publications

Performance Optimization of GaAs-Based Vertical-Cavity Surface-Emitting Transistor-Lasers

Performance Optimization of GaAs-Based Vertical-Cavity Surface-Emitting Transistor-Lasers

Analysis of Tunable Internal Loss Caused by Franz–Keldysh Absorption in Transistor Lasers

Investigation of effective base transit time and current gain modulation of light-emitting transistors under different ambient temperatures

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