Thermal and optical investigations of self-loop system based on liquid quantum dots for laser lighting

•A self-loop converter was designed to solve the thermal quenching problem of QDs.•QDs could maintain stable lighting for 240 min under the high-power laser.•Temperature fluctuation of QDs was significantly reduced. This study proposes a self-loop converter (SLC) based on liquid quantum dots (QDs) t...

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Veröffentlicht in:	Optics and laser technology 2022-08, Vol.152, p.108175, Article 108175
Hauptverfasser:	Ding, Xinrui, Song, Yaoxing, Tang, Xueting, Xu, Liang, Yuan, Yikai, Wei, Yuxin, Li, Zongtao
Format:	Artikel
Sprache:	eng
Schlagworte:	Coal mining Converters Flow cycle High power lasers Illumination Laser beam heating Laser lighting Lighting Liquid quantum dots Photochromic property Quantum dots Thermal management
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container_start_page	108175
container_title	Optics and laser technology
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creator	Ding, Xinrui Song, Yaoxing Tang, Xueting Xu, Liang Yuan, Yikai Wei, Yuxin Li, Zongtao
description	•A self-loop converter was designed to solve the thermal quenching problem of QDs.•QDs could maintain stable lighting for 240 min under the high-power laser.•Temperature fluctuation of QDs was significantly reduced. This study proposes a self-loop converter (SLC) based on liquid quantum dots (QDs) that is designed for laser lighting. QDs exhibit unique illumination and display advantages because of their high light conversion efficiency and color purity. However, the unavoidable heat generated during light conversion leads to thermal quenching and limits their application in high-power laser lighting. The proposed SLC reduces the temperature and temperature fluctuations in the excited heating and gas circulation areas. After excited by laser for 240 min, the radiation power only decreases from 529.65 mW to 464.13 mW, a decrease of 12.37%. But the radiation power of hermitic converter (HC) decreased from 520.52 mW to 361.35 mW, decreasing by 30.5% after excited by laser for the same time. The experimental results demonstrate that the proposed SLC is promising for laser headlights, aerospace, coal mining, and other fields.
doi_str_mv	10.1016/j.optlastec.2022.108175
format	Article
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subjects	Coal mining Converters Flow cycle High power lasers Illumination Laser beam heating Laser lighting Lighting Liquid quantum dots Photochromic property Quantum dots Thermal management
title	Thermal and optical investigations of self-loop system based on liquid quantum dots for laser lighting
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