Open AccessAn electrically pumped surface-emitting semiconductor green laser
Author(s) -
YongHo Ra,
Roksana Tonny Rashid,
Xianhe Liu,
Sharif Md. Sadaf,
Kishwar Mashooq,
Zetian Mi
Publication year - 2020
Publication title -
science advances
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 5.928
H-Index - 146
ISSN - 2375-2548
DOI - 10.1126/sciadv.aav7523
Subject(s) - optoelectronics , materials science , laser , distributed bragg reflector , diode , semiconductor , epitaxy , ultraviolet , semiconductor laser theory , light emitting diode , photonics , gallium nitride , substrate (aquarium) , optics , blue laser , nanotechnology , wavelength , layer (electronics) , physics , oceanography , geology
Surface-emitting semiconductor lasers have been widely used in data communications, sensing, and recently in Face ID and augmented reality glasses. Here, we report the first achievement of an all-epitaxial, distributed Bragg reflector (DBR)-free electrically injected surface-emitting green laser by exploiting the photonic band edge modes formed in dislocation-free gallium nitride nanocrystal arrays, instead of using conventional DBRs. The device operates at ~523 nm and exhibits a threshold current of ~400 A/cm, which is over one order of magnitude lower compared to previously reported blue laser diodes. Our studies open a new paradigm for developing low-threshold surface-emitting laser diodes from the ultraviolet to the deep visible (~200 to 600 nm), wherein the device performance is no longer limited by the lack of high-quality DBRs, large lattice mismatch, and substrate availability.
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