Performance optimization of multiple quantum well transistor laser

被引：23

作者：

机构：

[1] Beckman Institute for Advanced Science and Technology, University of Illinois at Urbana-Champaign, Urbana

[2] Department of Electrical Engineering, Photonics Research Laboratory, Amirkabir University of Technology

来源：

Taghavi, I. (itaghavi@illinois.edu) | 2013年 / Institute of Electrical and Electronics Engineers Inc., United States卷 / 49期

关键词：

Heterojunction bipolar transistor laser (HBTL); modeling; optical frequency response; rate equation;

D O I：

10.1109/JQE.2013.2250488

中图分类号：

学科分类号：

摘要：

A comprehensive physical model that emphasizes carrier tunneling between quantum wells (QWs) in the base of transistor lasers (TLs) is developed. This model relies on a set of multilevel coupled rate equations solved by computationally efficient numerical methods for simulating both steady state and transient TL operations. Our approach also features the explicit dependence of the structure design on device parameters such as optical confinement factor and carrier density-dependent gain. It also accounts for operation behaviors such as bandwidth roll-off and critical base width not yet addressed in the literature. Simulation results show significant enhancement in optical bandwidth as well as threshold current reduction when multiple QWs are incorporated within the base region. It predicts the dominance of tunneling transport of carriers for barriers thinner than 13.5 nm in a system with 7-nm QWs. However, the optimum QW number depends on the structure design as well as TL biasing conditions. For this purpose, we define a performance parameter as a TL figure of merit that can be maximized by optimizing both the base and the cavity designs. © 1965-2012 IEEE.

引用

页码：426 / 435

页数：9

共 36 条

[1]

Walter G., Holonyak Jr. N., Feng M., Chan R., Laser operation of a heterojunction bipolar light-emitting transistor, Applied Physics Letters, 85, 20, pp. 4768-4770, (2004)

[2]

Feng M., Then H.W., Holonyak Jr. N., Walter G., James A., Resonance-free frequency response of a semiconductor laser, Appl. Phys. Lett, 95, 3, pp. 0335091-0335093, (2009)

[3]

Basu R., Mukhopadhyay B., Basu P.K., Modeling resonance-free modulation response in transistor lasers with single and multiple quantum wells in the base, IEEE Photon. J, 4, 5, pp. 1572-1581, (2012)

[4]

Feng M., Holonyak N., James A., Cimino K., Walter G., Chan R., Carrier lifetime and modulation bandwidth of a quantum well AlGaAs/InGaP/GaAs/InGaAs transistor laser, Appl. Phys. Lett, 89, 11, pp. 1135041-1135043, (2006)

[5]

Walter G., James A., Holonyak Jr. N., Feng M., Chirp in a transistor laser: Franz-Keldysh reduction of the linewidth enhancement, Appl. Phys. Lett, 90, 9, pp. 0911091-0911093, (2007)

[6]

Feng M., Holonyak Jr. N., Then H.W., Walter G., Charge control analysis of transistor laser operation, Appl. Phys. Lett, 91, 5, pp. 0535011-0535013, (2007)

[7]

Faraji B., Shi W., Pulfrey D.L., Chrostowski L., Analytical modeling of the transistor laser, IEEE J. Sel. Topics Quantum Electron, 15, 3, pp. 594-603, (2009)

[8]

Zhang L., Leburton J.P., Modeling of the transient characteristics of heterojunction bipolar transistor lasers, IEEE J. Quantum Electron, 45, 4, pp. 359-366, (2009)

[9]

Basu R., Mukhopadhyay B., Basu P.K., Estimated threshold base current and light power output of a transistor laser with InGaAs quantum well in GaAs base, Semicond. Sci. Technol, 26, 10, pp. 1050141-1050143, (2011)

[10]

Basu R., Mukhopadhyay B., Basu P.K., Modeling of current gain compression in common emitter mode of a transistor laser above threshold base current, J. Appl. Phys, 111, 8, pp. 0831031-0831037, (2012)

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