The design of short wavelength light emitting diodes

2012 ◽  
Author(s):  
Zhibin Zhao ◽  
Qu Yi Li Te ◽  
Yang Hao ◽  
Yu Shuai ◽  
Liu Lei ◽  
...  
Keyword(s):  
Short Wavelength ◽  
Light Emitting Diodes ◽  
Light Emitting ◽  
Short Wavelength Light ◽  
Wavelength Light

A Simple Reliable Method of Selecting Epoxy Molding Compounds for High Power Short Wavelength Light Emitting Diode Packages

2006 ◽  
Vol 510-511 ◽  
pp. 154-157
Author(s):  
Chong Mu Lee ◽  
Seung Mo Kang ◽  
Keun Bin Yim ◽  
Sook Joo Kim ◽  
Hyoun Woo Kim
Keyword(s):  
High Power ◽  
Short Wavelength ◽  
Reliable Method ◽  
Light Emitting Diode ◽  
Thermal Stabilities ◽  
Light Emitting ◽  
Molding Compounds ◽  
Weight Losses ◽  
Short Wavelength Light ◽  
Wavelength Light

Epoxy molding compounds (EMC) with higher thermal stabilities are urgently needed as the light emitting diode (LED) becomes brighter and the wavelength of the its light becomes shorter. This paper proposes a simple reliable method of evaluating the thermal stabilities of commercial EMCs. The transmittances of most commercial EMC samples for high power short wavelength LED packages were decreased by heat treatment at 150oC for 200hr. Also the thermal stabilities of the samples were confirmed by measuring the weight losses through TGA. The experimental results suggest that employing a good heatsink is indispensable in highly bright short wavelength LED packages.

scholarly journals 0172 Blue-Light Blockers and Sleep: A Meta-Analysis of Intervention Studies

SLEEP ◽  
2020 ◽  
Vol 43 (Supplement_1) ◽  
pp. A68-A69
Author(s):  
A Shechter ◽  
K A Quispe ◽  
J S Mizhquiri Barbecho ◽  
L Falzon
Keyword(s):  
Short Wavelength ◽  
Light Exposure ◽  
Meta Analysis ◽  
Electronic Devices ◽  
Sleep Onset ◽  
Sleep Time ◽  
Combined Effect ◽  
Light Emitting ◽  
Short Wavelength Light ◽  
Wavelength Light

Abstract Introduction Sleep and circadian physiology are influenced by external light, particularly within the short-wavelength portion of the visible spectrum (~450–480 nm). Most personal light-emitting electronic devices (e.g., tablets, smartphones, computers) are enriched in this so-called “blue” light. Interventions to reduce short-wavelength light exposure to the eyes before bedtime may help mitigate adverse effects of light-emitting electronic devices on sleep. Methods We conducted a meta-analysis of intervention studies on the effects of wearing color-tinted lenses (e.g., orange or amber) in frames in the evening before sleep to selectively filter short-wavelength light exposure to the eyes. Outcomes were self-reported or objective (wrist-accelerometer) measures of nocturnal sleep. Databases (MEDLINE, EMBASE, Cochrane Library, PsycINFO, CINAHL, AMED) were searched from inception to November 2019. PROSPERO Registration: CRD42018105854. Results Ten studies were identified (7 randomized controlled trials; 3 before-after studies). Findings of individual studies were inconsistent, with some showing benefit and others showing no effect of intervention. For objective sleep onset latency, there was a significant modest-sized combined effect (Hedge’s g=-0.52, 95% CI: -1.27-0.24, Z=-2.94, p=0.003, I2=16.6%, k=3). There was a minor but non-statistically significant combined effect for objective sleep efficiency (Hedge’s g=0.24, 95% CI: -0.16–0.64, Z=1.69, p=0.09, I2=23.7%, k=5). There were no significant combined effects for objective measures of total sleep time and wake after sleep onset. For self-reported total sleep time, there was a statistically significant medium-sized combined effect (Hedge’s g=0.61, 95% CI: 0.14–1.09, Z=5.56, p<0.01, I2=0%, k=3). Conclusion There is mixed evidence that this approach can improve sleep. Relatively few studies have been conducted, and most did not assess light levels or melatonin. The “blue-blocker” intervention may be particularly useful in individuals with insomnia, delayed sleep phase syndrome, or attention-deficit hyperactive disorder. Considering the ubiquitousness of short wavelength-enriched light sources and the potential for widespread sleep disturbance, future controlled studies examining the efficacy of this approach to improve sleep are warranted. Support N/A

Blue light from light-emitting diodes elicits a dose-dependent suppression of melatonin in humans

2011 ◽  
Vol 110 (3) ◽  
pp. 619-626 ◽  
Author(s):  
Kathleen E. West ◽  
Michael R. Jablonski ◽  
Benjamin Warfield ◽  
Kate S. Cecil ◽  
Mary James ◽  
...  
Keyword(s):  
Short Wavelength ◽  
Healthy Subjects ◽  
Response Curve ◽  
Light Emitting Diodes ◽  
Fluorescent Light ◽  
Light Emitting ◽  
Blue Led ◽  
Led Light ◽  
Melatonin Suppression ◽  
Wavelength Light

Light suppresses melatonin in humans, with the strongest response occurring in the short-wavelength portion of the spectrum between 446 and 477 nm that appears blue. Blue monochromatic light has also been shown to be more effective than longer-wavelength light for enhancing alertness. Disturbed circadian rhythms and sleep loss have been described as risk factors for astronauts and NASA ground control workers, as well as civilians. Such disturbances can result in impaired alertness and diminished performance. Prior to exposing subjects to short-wavelength light from light-emitting diodes (LEDs) (peak λ = 469 nm; ½ peak bandwidth = 26 nm), the ocular safety exposure to the blue LED light was confirmed by an independent hazard analysis using the American Conference of Governmental Industrial Hygienists exposure limits. Subsequently, a fluence-response curve was developed for plasma melatonin suppression in healthy subjects ( n = 8; mean age of 23.9 ± 0.5 years) exposed to a range of irradiances of blue LED light. Subjects with freely reactive pupils were exposed to light between 2:00 and 3:30 AM. Blood samples were collected before and after light exposures and quantified for melatonin. The results demonstrate that increasing irradiances of narrowband blue-appearing light can elicit increasing plasma melatonin suppression in healthy subjects ( P < 0.0001). The data were fit to a sigmoidal fluence-response curve ( R2 = 0.99; ED50 = 14.19 μW/cm2). A comparison of mean melatonin suppression with 40 μW/cm2 from 4,000 K broadband white fluorescent light, currently used in most general lighting fixtures, suggests that narrow bandwidth blue LED light may be stronger than 4,000 K white fluorescent light for suppressing melatonin.

scholarly journals Demonstration of epitaxial growth of strain-relaxed GaN films on graphene/SiC substrates for long wavelength light-emitting diodes

2021 ◽  
Vol 10 (1) ◽  
Author(s):  
Ye Yu ◽  
Tao Wang ◽  
Xiufang Chen ◽  
Lidong Zhang ◽  
Yang Wang ◽  
...  
Keyword(s):  
Epitaxial Growth ◽  
Light Emitting Diodes ◽  
Nitrogen Plasma ◽  
Biaxial Stress ◽  
Organic Chemical ◽  
Graphene Surface ◽  
Light Emitting ◽  
Long Wavelength ◽  
Pre Treatment ◽  
Wavelength Light

AbstractStrain modulation is crucial for heteroepitaxy such as GaN on foreign substrates. Here, the epitaxy of strain-relaxed GaN films on graphene/SiC substrates by metal-organic chemical vapor deposition is demonstrated. Graphene was directly prepared on SiC substrates by thermal decomposition. Its pre-treatment with nitrogen-plasma can introduce C–N dangling bonds, which provides nucleation sites for subsequent epitaxial growth. The scanning transmission electron microscopy measurements confirm that part of graphene surface was etched by nitrogen-plasma. We study the growth behavior on different areas of graphene surface after pre-treatment, and propose a growth model to explain the epitaxial growth mechanism of GaN films on graphene. Significantly, graphene is found to be effective to reduce the biaxial stress in GaN films and the strain relaxation improves indium-atom incorporation in InGaN/GaN multiple quantum wells (MQWs) active region, which results in the obvious red-shift of light-emitting wavelength of InGaN/GaN MQWs. This work opens up a new way for the fabrication of GaN-based long wavelength light-emitting diodes.

scholarly journals Restricting short-wavelength light in the evening to improve sleep in recreational athletes – A pilot study

2018 ◽  
Vol 19 (6) ◽  
pp. 728-735 ◽  
Author(s):  
Melanie Knufinke ◽  
Lennart Fittkau-Koch ◽  
Els I. S. Møst ◽  
Michiel A. J. Kompier ◽  
Arne Nieuwenhuys
Keyword(s):  
Pilot Study ◽  
Short Wavelength ◽  
Recreational Athletes ◽  
Short Wavelength Light ◽  
Wavelength Light
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