SSL Lab. SSL Lab. Solid State Lighting Lab. Southern Taiwan University 1 Adviser : Hon Kuan Reporter: Wei-Shun Huang Southern Taiwan University Efficient.

Slides:

Advertisements

Similar presentations

The combination of solid state physics and Maxwell’s equations has resulted in the development of photonic crystals, which offer novel ways of manipulating.

Advertisements

USING LIGHT EMITTING DIODES FOR LIGHTING BY: GRANT GORMAN AND ALEC PAHL 5/6/2013 ABSTRACT: LIGHT EMITTING DIODES ARE SEMICONDUCTOR DEVICES THAT EMIT LIGHT.

1 Light-emitting Diodes Light-emitting Diodes for general lighting applications D.L. Pulfrey Department of Electrical and Computer Engineering University.

LED design has evolved to increase extraction efficiency, but all forms have the same basic epilayer structure (a). Metallic contacts can be added to this.

Simulation of InGaN violet and ultraviolet multiple-quantum-well laser diodes Sheng-Horng Yen, Bo-Jean Chen, and Yen-Kuang Kuo* *Department of Physics,

Photometry of LED Lighting Devices

Quantum Dot White LEDs Jennifer Asis EECS 277A. Motivation Science Energy efficient Long life Durable Small size Design flexibility.

LED Lights vs. Incandescent Lights vs. CFLs. What are LEDS ? LEDs, or light–emitting diodes, are semiconductor devices that produce visible light when.

LEDs: Lighting the Future Presenter: Ted Kretschmer, Mechanical Engineering Mentors: Dr. Xuejun Fan, Mechanical Engineering Dr. Liangbiao Chen, Mechanical.

Reflectance Spectroscopy Lab. Different colors correspond to different wavelengths of visible light 665 nm 630 nm 600 nm 550 nm 470 nm 425 nm 400 nm.

Solid State Lighting: The Future is here Xavier Fernando Ryerson University.

Filter Set Selection. It is best to follow this presentation with a Fluorophore excitation/emission maxima chart to hand.

APPLIED PHYSICS LETTERS 96, , 2010

JY Tsao ∙ Ultra-Efficient Solid-State Lighting ∙ IEEE LEOS Newport Beach ∙ Nov 2008 Ultra-Efficient Solid-State Lighting: Performance Frontier, Progress,

Page 1 Band Edge Electroluminescence from N + -Implanted Bulk ZnO Hung-Ta Wang 1, Fan Ren 1, Byoung S. Kang 1, Jau-Jiun Chen 1, Travis Anderson 1, Soohwan.

Uniform Illumination with LED based lighting CIE Div1 Meeting june 2008.

1 ISAT 413 ─ Module II:Lighting Topic 4: Energy efficient lighting technologies and their applications (3)  Latest Technologies in Lighting: Solid-State.

A Stable Zn-indiffused LiNbO 3 Mode Converter at μm Wavelength STUT Hsuan-Hsien Lee 2, Ruey-Ching Twu 1, Hao-Yang Hong 1, and Chin-Yau Yang 1 1.

LED / OLED Advisor ： Ru-Li Lin Student ： Liang-Yan Li Date ： 2013 / 4 / 8 Southern Taiwan University of Science and Technology Department of Mechanical.

SSL Lab. SSL Lab. Solid State Lighting Lab. Southern Taiwan University 1 Adviser : Hon Kuan Adviser : Hon Kuan Wen-Cheng Tzou Wen-Cheng Tzou Reporter :

H. Choukri, A.Fischer, S. Forget, S. Chénais, M.-C. Castex, Lab. de Physique des Lasers, Univ. Paris Nord, France Color-control (including White) in OLEDs.

JY Tsao ∙ SAND C ∙ Photonics West 2010 Jan 26 ∙ 1/8 (Lighting and) Solid-State Lighting: Science, Technology, Economic Perspectives Work at Sandia.

Color in image and video Mr.Nael Aburas. outline  Color Science  Color Models in Images  Color Models in Video.

Influence of oxygen content on the 1.54 μm luminescenceof Er-doped amorphous SiO x thin films G.WoraAdeola,H.Rinnert *, M.Vergnat LaboratoiredePhysiquedesMate´riaux.

Fundamentals of Multimedia Chapter 4 : Color in Image and Video 2 nd Edition 2014 Ze-Nian Li Mark S. Drew Jiangchuan Liu 1.

WHITE LED S Yogesh Kumar 2008ph10643 Group no. 3 Course- EPL335.

Correlation between visual impression and instrumental colour determination for LEDs János Schanda Professor Emeritus of the University of Pannonia, Hungary.

 Top DBR mirror replaced with CTF and chiral STF bilayers  The CTF (QWP) introduces a pi/2 retardance to compensate the polarization mismatch between.

The Analysis of Light Absorption and Extraction of InGaN LEDs Jeng-Feng Lin, Chin-Chieh Kang, Pei-Chiang Kao Department of Electro-Optical Engineering,

Accelerated Life Test of High Brightness Light Emitting Diodes 陳詠升.

Plank Formula The 1900 quantum hypothesis by Max Planck that any energy is radiated and absorbed in quantities divisible by discrete ‘energy elements’,

日期：指導老師：林克默、黃文勇學生：陳立偉 1. Outline 1.Introduction 2.Experimental 3.Result and Discussion 4.Conclusion 2.

A. Fischer, S. Forget, S. Chénais, M.-C. Castex, Lab. de Physique des Lasers, Univ. Paris Nord, France Highly efficient multilayer organic pure-blue- light.

Advisor: Prof. Yen-Kuang Kuo

JY Tsao ∙ Evolution of Solid-State Lighting: Market Pull and Technology Push ∙ Xiamen ∙ 2005 Apr 13 Evolution of Solid-State Lighting: Market Pull and.

Enhancing the Macroscopic Yield of Narrow-Band High-Order Harmonic Generation by Fano Resonances Muhammed Sayrac Phys-689 Texas A&M University 4/30/2015.

FIG. 4. Electroluminescence spectra of (a) Sample A (with shallow TQW), (b) Sample B (with shallow RQW), (c) Sample C (w/o. shallow QWs) at Various injection.

Three-Receptor Model Designing a system that can individually display thousands of colors is very difficult Instead, colors can be reproduced by mixing.

Use different substrate for InGaN-GaN LED 陳詠升. Outline Introduction Experiment Results and Discussion Conclusion References.

Quenching of Fluorescence and Broadband Emission in Yb 3+ :Y 2 O 3 and Yb 3+ :Lu 2 O 3 3rd Laser Ceramics Symposium : International Symposium on Transparent.

Lab 5 – Emission Spectra.

 Introduction  Literature Review  Motivation  Experimental  Results and Discussion  Conclusion  Future work  References 2.

1 Enhanced efficiency of GaN-based light-emitting diodes with periodic textured Ga-doped ZnO transparent contact layer 指導教授 : 管鴻 (Hon Kuan) 老師學生 : 李宗育.

Relationship between thermal and luminance distributions in high-power lateral GaN/InGaN light-emitting diodes D.P. Han, J.I. Shim and D.S. Shin ELECTRONICS.

Optoelectronic Devices Text, Chapter 11 Sze is a good reference.

Adviser : Ming-Shyong Tsai Date : 2012/03/21

Y.W. Lin. Outline Introduction Experiments Results and Discussion Conclusion References.

3. OLED panel Organic light emitting diodes (OLEDs) with a quasi-crystal (QC) structure are analyzed and applied in a head-mounted display (HMD) system.

Experimental Details 1 Fig. 1. Schematic diagram of the investigated LED layer structure. In the present work, the Mg doping width of the LT p-GaN interlayer.

Date of download: 6/2/2016 Copyright © 2016 SPIE. All rights reserved. Candle shows different color temperatures (CTs) at different positions inside the.

Optical Design of Phosphor Sheet Structure in LED Backlight System

GaN-Based MSM Photodetectors Prepared on Patterned Sapphire Substrates Shoou-Jinn Chang, Member, IEEE, Y. D. Jhou, Y. C. Lin, S. L. Wu, C. H. Chen, T.

Date of download: 6/22/2016 Copyright © 2016 SPIE. All rights reserved. Index-matching effect. Matching the index of refraction of the bead with the solution.

Organic Light Emitting Devices (OLEDs). 2 OLED is the acronym for Organic Light Emitting Diode An OLED is a solid-state device composed of thin films.

Date of download: 6/23/2016 Copyright © 2016 SPIE. All rights reserved. Principles of outcoupling in organic light-emitting diodes (OLEDs). (a) Illustration.

Reporter: Chien-Chung Tsai

Fig. 4. Simulated thermal distributions of (a) the designed thermal expander, (b) the referenced Material I (Copper) sample, and (c) the referenced Material.

정보통신프로젝트 Influence of the Size of a Phosphor Particle on Color Characteristics of a White LED Dong-hyun Lee, Sun-hong KIM (School of.

Speaker: Bo-Wen Xiao ( 蕭博文 ) Advisor: Prof. Yi-Pai Huang ( 黃乙白教授 ) Prof. Chung-Hao Tien( 田仲豪教授 ) Institute of Electro-Optical Engineering, National Chiao.

Date of download: 9/18/2016 Copyright © 2016 SPIE. All rights reserved. OLEDs can be free of UV, IR, glare, and spiking emission. Figure Legend: From:

Date of download: 9/19/2016 Copyright © 2016 SPIE. All rights reserved. Schematic diagram of the surface-mounted device (SMD) and chip-scale package (CSP)

Sol–gel preparation of efficient red phosphor Mg2TiO4:Mn4+ and XAFS investigation on the substitution of Mn4+ for Ti4+ Tiannan Ye, Shan Li, Xueyan Wu,

Y. Zhu, C. L. Yuan, S. L. Quek, S. S. Chan, and P. P. Ong

Luminescent Periodic Microstructures for Medical Applications

Ken-Chia Chang, and Ming-Dar Wei* *

High-efficiency green light-emitting diodes

Optoelectronic Devices

Fluorescence of Samarium Ions in Strontium Bismuth Borate Glasses

Eye Sensitivity under Scotopic (Rod) and Photopic (cone) Conditions

Presentation transcript:

SSL Lab. SSL Lab. Solid State Lighting Lab. Southern Taiwan University 1 Adviser : Hon Kuan Reporter: Wei-Shun Huang Southern Taiwan University Efficient and stable laser-driven white lighting

SSL Lab. SSL Lab. Solid State Lighting Lab. Southern Taiwan University 2 Outline Introduction Experiments Result and Discussion Conclusion References

SSL Lab. SSL Lab. Solid State Lighting Lab. Southern Taiwan University 3 Introduction

SSL Lab. SSL Lab. Solid State Lighting Lab. Southern Taiwan University 4 Solid-state white lighting has gained interest since the development of candela-class, high brightness InGaN light emitting diodes by Nakamura and coworkers in This development, in combination with appropriate phosphor compositions and improvements in devicepackaging, have led to devices that use less energy and are a viable option to replace conventional incandescent or fluorescent light sources. 2 Traditional solid-state white lighting devices comprise a blue or near-UV LED as the excitation source and one or more phosphor compositions which down-convert all or part of the LED emission to longer wavelengths.

SSL Lab. SSL Lab. Solid State Lighting Lab. Southern Taiwan University 5 FIG. 1.Excitation and emission spectra, collected at the relative maxima (a) the blue-emitting phosphor (λex = 335 nm;λem = 452 nm), (b) the green-emitting phosphor (λex = 395 nm; λem = 530 nm), (c) the red-emitting phosphor (λex= 395 nm; λem = 630 nm). (d) shows the relative emission intensities collected at 402 nm excitation.

SSL Lab. SSL Lab. Solid State Lighting Lab. Southern Taiwan University 6 Experiments

SSL Lab. SSL Lab. Solid State Lighting Lab. Southern Taiwan University Schematic illustrations of the experimental setup used to measure laser excited phosphor samples in an integrating sphere. The phosphor encapsulated silicone disk, mounted on a transparent quartz substrate, is positioned with the surface at a slight angle to the incoming laser beam. The resulting device operates in reflection mode due to the dense phosphor pellet,illustrated for(A)the near-UV excited RGB phosphors(B)the blue excited YAG:Ce.

SSL Lab. SSL Lab. Solid State Lighting Lab. Southern Taiwan University 8 SampleCCT(K)Raφv (lm)ηv (lm/W) RGB RGB YAG TABLE1.Measured properties including the correlated color temperature, color rendering, luminous flux,and luminous efficacy of the resulting white light using the near-UV(λmax = 402 nm) laser diode in combination with phosphor samples RGB1 and RGB2 and using the blue (λmax = 442 nm) laser diode in combination with YAG.

SSL Lab. SSL Lab. Solid State Lighting Lab. Southern Taiwan University 9 Result and Discussion

SSL Lab. SSL Lab. Solid State Lighting Lab. Southern Taiwan University 10 FIG. 3. SPD for phosphor samples (a)RGB1 (b)RGB2 excited using a near-UV (λmax = 402 nm) laser diode (c)The corresponding CIE chromaticity coordinates show white light with a variety of color temperatures is attainable. Photographs of the RGB2 phosphor sample (d) without and (e) with laser excitation.

SSL Lab. SSL Lab. Solid State Lighting Lab. Southern Taiwan University 11 FIG. 4. (a) Calculated SPD for target white light composed of YAG:Ce and a blue laser diode, (b) experimentally measured SPD with a similar ratio of laser to phosphor emission as that of the calculated SPD, (c) the corresponding CIE chromaticity coordinates, and a photograph of the YAG:Ce phosphor sample (d) without and (e) with laser excitation. The SPDs show the fits to three Gaussian curves, representing the fraction of emitted white light from laser emission and phosphor emission.

SSL Lab. SSL Lab. Solid State Lighting Lab. Southern Taiwan University We have also shown that the luminous fficacy of such a device can be improved by stimating the maximum efficacy and altering the ratio of laser emission to phosphor emission in order to reach this maximum efficacy. Further improvements in these devices can be envisioned through advancements in laser diode technologies and optimization of device packaging and phosphor properties. 12 Conclusion

SSL Lab. SSL Lab. Solid State Lighting Lab. Southern Taiwan University 13 References 1.S. Nakamura, T. Mukai, and M. Senoh, Appl. Phys. Lett. 64, 1687 (1994). 2.E. F. Schubert, Light-Emitting Diodes (Cambridge University Press, 2006). 3.N. C. George, K. A. Denault, and R. Seshadri, Annu. Rev. Mater. Res. 43 (2013). 4.Y. Ohno, Proc. of SPIE 5530, 88 (2004). 5.Z. Liu, T. Wei, E. Guo, X. Yi, L. Wang, J. Wang, G. Wang, Y. Shi, I. Ferguson, and J. Li, Appl. Phys. Lett. 99, (2011). 6.J. H. Son and J.-L. Lee, Opt. Express 18, 5466 (2010). 7.Y. Xu, L. Chen, Y. Li, G. Song, Y. Wang, W. Zhuang, and Z. Long, Appl. Phys. Lett. 92, (2008). 8.Y. Xu, H. Hu, W. Zhuang, G. Song, Y. Li, and L. Chen, Laser Phys. 19, 403 (2009). 9.H.-Y. Ryu and D.-H. Kim, J. Opt. Soc. Korea 14, 415 (2010).

SSL Lab. SSL Lab. Solid State Lighting Lab. Southern Taiwan University 14 T hanks for your attention !