GaSb-Based Type-I Quantum Well 3-3.5-μ m Cascade Light Emitting Diodes

Maksim Ermolaev; Youxi Lin; Leon Shterengas; Takashi Hosoda; Gela Kipshidze; Sergey Suchalkin; Gregory Belenky

doi:10.1109/LPT.2018.2822621

GaSb-Based Type-I Quantum Well 3-3.5-μ m Cascade Light Emitting Diodes

Maksim Ermolaev
, Youxi Lin
, Leon Shterengas
, Takashi Hosoda
, Gela Kipshidze
, Sergey Suchalkin
, Gregory Belenky

Electrical Engineering

Stony Brook University

Stony Brook University

Research output: Contribution to journal › Article › peer-review

19 Scopus citations

Abstract

Mid-infrared light emitting diodes based on cascade pumping of the type-I quantum wells were designed and fabricated. The 500- μm -diameter mesa ten-stage devices emitted more than 2 mW of continuous wave power in a wide spectrum peaking at 3.1μm at room temperature. More than 6 mW was obtained at 77 K. The above-mentioned output power levels were measured from an uncoated window in the substrate-side contact metallization of epi-side-down mounted emitters. The maximum output power and the device operating voltage are roughly scaled with the number of cascades in the device heterostructure. The low-current device slope efficiency per stage decreased with increasing the acceptor doping level in the layers adjacent to the active quantum wells. Increase of the number of quantum wells in each stage from one to three led to about 25% improvement of the output power at 300 K.

Original language	English
Pages (from-to)	869-872
Number of pages	4
Journal	IEEE Photonics Technology Letters
Volume	30
Issue number	9
DOIs	https://doi.org/10.1109/LPT.2018.2822621
State	Published - May 1 2018

Keywords

GaSb-based
Infrared
cascade pumping
type-I quantum well

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10.1109/LPT.2018.2822621

Cite this

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title = "GaSb-Based Type-I Quantum Well 3-3.5-μ m Cascade Light Emitting Diodes",

abstract = "Mid-infrared light emitting diodes based on cascade pumping of the type-I quantum wells were designed and fabricated. The 500- μm -diameter mesa ten-stage devices emitted more than 2 mW of continuous wave power in a wide spectrum peaking at 3.1μm at room temperature. More than 6 mW was obtained at 77 K. The above-mentioned output power levels were measured from an uncoated window in the substrate-side contact metallization of epi-side-down mounted emitters. The maximum output power and the device operating voltage are roughly scaled with the number of cascades in the device heterostructure. The low-current device slope efficiency per stage decreased with increasing the acceptor doping level in the layers adjacent to the active quantum wells. Increase of the number of quantum wells in each stage from one to three led to about 25\% improvement of the output power at 300 K.",

keywords = "GaSb-based, Infrared, cascade pumping, type-I quantum well",

author = "Maksim Ermolaev and Youxi Lin and Leon Shterengas and Takashi Hosoda and Gela Kipshidze and Sergey Suchalkin and Gregory Belenky",

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T1 - GaSb-Based Type-I Quantum Well 3-3.5-μ m Cascade Light Emitting Diodes

AU - Ermolaev, Maksim

AU - Lin, Youxi

AU - Shterengas, Leon

AU - Hosoda, Takashi

AU - Kipshidze, Gela

AU - Suchalkin, Sergey

AU - Belenky, Gregory

PY - 2018/5/1

Y1 - 2018/5/1

N2 - Mid-infrared light emitting diodes based on cascade pumping of the type-I quantum wells were designed and fabricated. The 500- μm -diameter mesa ten-stage devices emitted more than 2 mW of continuous wave power in a wide spectrum peaking at 3.1μm at room temperature. More than 6 mW was obtained at 77 K. The above-mentioned output power levels were measured from an uncoated window in the substrate-side contact metallization of epi-side-down mounted emitters. The maximum output power and the device operating voltage are roughly scaled with the number of cascades in the device heterostructure. The low-current device slope efficiency per stage decreased with increasing the acceptor doping level in the layers adjacent to the active quantum wells. Increase of the number of quantum wells in each stage from one to three led to about 25% improvement of the output power at 300 K.

AB - Mid-infrared light emitting diodes based on cascade pumping of the type-I quantum wells were designed and fabricated. The 500- μm -diameter mesa ten-stage devices emitted more than 2 mW of continuous wave power in a wide spectrum peaking at 3.1μm at room temperature. More than 6 mW was obtained at 77 K. The above-mentioned output power levels were measured from an uncoated window in the substrate-side contact metallization of epi-side-down mounted emitters. The maximum output power and the device operating voltage are roughly scaled with the number of cascades in the device heterostructure. The low-current device slope efficiency per stage decreased with increasing the acceptor doping level in the layers adjacent to the active quantum wells. Increase of the number of quantum wells in each stage from one to three led to about 25% improvement of the output power at 300 K.

KW - GaSb-based

KW - Infrared

KW - cascade pumping

KW - type-I quantum well

UR - https://www.scopus.com/pages/publications/85044767343

U2 - 10.1109/LPT.2018.2822621

DO - 10.1109/LPT.2018.2822621

M3 - Article

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VL - 30

SP - 869

EP - 872

JO - IEEE Photonics Technology Letters

JF - IEEE Photonics Technology Letters

IS - 9

ER -

GaSb-Based Type-I Quantum Well 3-3.5-μ m Cascade Light Emitting Diodes

Abstract

Keywords

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