مرکز منطقه ای اطلاع رساني علوم و فناوري - Observation and Modeling of a Room-Temperature Negative Characteristic Temperature 1.3-<formula formulatype="inline"> <img src="/images/tex/241.gif" alt="\\mu"> </formula>m p-Type Modulation-Doped Quantum-Dot Laser

DocumentCode :

833208

Title :

Observation and Modeling of a Room-Temperature Negative Characteristic Temperature 1.3- $\\mu$ m p-Type Modulation-Doped Quantum-Dot Laser

Author :

Jin, Chao-Yuan ; Badcock, Tom J. ; Liu, Hui-Yun ; Groom, Kristian M. ; Royce, Richard J. ; Mowbray, David J. ; Hopkinson, Mark

Author_Institution :

Dept. of Electron. & Electr. Eng., Univ. of Sheffield

Volume :

Issue :

fYear :

2006

Firstpage :

1259

Lastpage :

1265

Abstract :

A room-temperature negative characteristic temperature (T₀) and ultralow threshold current density (J_th) of 48 Amiddotcm^-2 are demonstrated for a 1.3-mum InAs quantum dot laser. These characteristics are obtained by combining a high-growth-temperature GaAs spacer layer with p-type modulation doping of the quantum dots in multiple layer dot-in-a-well structures. Through a comparison of p-doped and undoped devices, a photon coupling mechanism is proposed to account for the different temperature dependences of Jth for the two devices. Numerical simulations based on a rate equation model, which includes photon coupling between ground and excited quantum dot states, are performed. The simulations are able to account for the very different temperature-dependent Jth behavior of the doped and undoped device

Keywords :

III-V semiconductors; current density; excited states; ground states; indium compounds; optical modulation; quantum dot lasers; semiconductor doping; 1.3 mum; 293 to 298 K; InAs; InAs quantum-dot laser; excited quantum dot states; ground quantum dot states; multiple layer dot-in-a-well structure; negative characteristic temperature; p-type modulation doping; photon coupling; threshold current density; Epitaxial layers; Equations; Gallium arsenide; Land surface temperature; Numerical simulation; Quantum dot lasers; Quantum dots; Semiconductor process modeling; Temperature dependence; Threshold current; ${hbox {p}}$-type modulation doping; Characteristic temperature $(T_{0})$; quantum-dot (QD) laser; threshold current density;

fLanguage :

English

Journal_Title :

Quantum Electronics, IEEE Journal of

Publisher :

ieee

ISSN :

0018-9197

Type :

jour

DOI :

10.1109/JQE.2006.883473

Filename :

4015585

Link To Document :

https://search.ricest.ac.ir/dl/search/defaultta.aspx?DTC=49&DC=833208