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1 Light Emitting Diodes and Solid-State Lighting Solid-state lighting PDF

82 Pages·2010·4.87 MB·English
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Preview 1 Light Emitting Diodes and Solid-State Lighting Solid-state lighting

Light Emitting Diodes and Solid-State Lighting E. Fred Schubert Department of Electrical, Computer, and Systems Engineering Department of Physics, Applied Physics, and Astronomy Rensselaer Polytechnic Institute, Troy, NY 12180 Phone: 518-276-8775 Email: OLED versus LED Opto Tech Corp. Osram Corp. OLEDs are area sources LEDs are point sources They do do not blind They are blindingly bright Suitable for large-area sources Suitable for imaging-optics applications 2 4 2 ƒ Luminance of OLEDs: 10 – 10 cd/m 6 7 2 ƒ Luminance of LEDs: 10 – 10 cd/m ƒ Luminance of OLEDs is about 4 orders of magnitude lower 4 ƒ OLED manufacturing cost per unit area must be 10 u lower OLEDs LEDs Low-cost reel-to-reel manufacturing Expensive epitaxial growth 3 of 164 Quantification of solid-state lighting benefits ƒ Energy benefits • 22 % of electricity used for lighting • LED-based lighting can be 20 u more efficient than incandescent and 5u more efficient than fluorescent lighting ƒ Environmental and economic benefits • Reduction of CO2 emissions, a global warming gas • Reduction of SO2 emissions, acid rain • Reduction of Hg emissions by coal-burning power plants • Reduction of hazardous Hg in homes ƒ Financial benefits • Electrical energy cost reduction, but also savings resulting from less pollution, global warming Hg Cause: CO2 Cause: SO2 CO2 ,SO2, NOx, Hg, U Cause: Waste heat and acid rain Antarctica Czech Republic Switzerland United States 4 of 164 2 Quantification of benefits Global benefits enabled by solid-state lighting technology over period of 10 years. First numeric value in each box represents annual US value. The USA uses about ¼ of world’s energy. Savings under “11% scenario” Reduction in total energy consumption 43.01 u 1018 J u 11% u 4 u 10 = = 189.2 u 1018 J Reduction in electrical energy consumption 457.8 TWh u 4 u 10 = = 18,310 TWh = 65.92 u 1018 J Financial savings 45.78 u 109 $ u 4 u 10 = = 1,831 u 109 $ Reduction in CO2 emission 267.0 Mt u 4 u 10 = 10.68 Gt Reduction of crude-oil consumption (1 barrel = 159 24.07 u 106 barrels u 4 u 10 = = 962.4 u 106 liters) barrels Number of power plants not needed 70 u 4 = 280 Schubert et al., Reports on Progress (*) 1.0 PWh = 1000 TWh = 11.05 PBtu = 11.05 quadrillion Btu “=” 0.1731 Pg of C = 173.1 Mtons of C 1 kg of C “=” [(12 amu + 2 u 16 amu) / 12 amu] kg of CO2 = 3.667 kg of CO2 in Physics 69, 3069 (2006) 5 of 164 History of LEDs ƒ Henry Joseph Round (1881 – 1966) ƒ 1907: First observation of electroluminescence ƒ 1907: First LED ƒ LED was made of SiC, carborundum, an abrasive material Henry Joseph Round 6 of 164 3 Light-Emitting Diode – 1924 – SiC – Lossev ƒ Oleg Vladimirovich Lossev (1903 – 1942) ƒ Brilliant scientist who published first paper at the age of 20 years ƒ The Lossevs were noble family of a Russian Imperial Army officer ƒ Lossev made first detailed study of electroluminescence in SiC ƒ Lossev concluded that luminescence is no heat glow (incandescence) ƒ Lossev noted similarity to vacuum gas discharge Oleg Vladimirovich Lossev SiC – Carborundum 7 of 164 Light-Emitting Diode – 1924 – SiC – Lossev ƒ Oleg V. Lossev noted light emission for forward and reverse voltage ƒ Measurement period 1924 – 1928 First photograph of LED Lossev’s I-V characteristic 8 of 164 4 Light emission in first LED ƒ First LED did not have pn junction! ƒ Light was generated by either minority carrier injection (forward) or avalanching (reverse bias) ƒ “Beginner’s luck” 9 of 164 History of AlGaAs IR and red LEDs ƒ There is lattice mismatch between AlGaAs and GaAs ƒ Growth by liquid phase epitaxy (LPE) ƒ Growth technique to date: Organometallic vapor Phase epitaxy 10 of 164 5 One of the first application of LEDs ƒ LEDs served to verify function of printed circuit boards (PCBs) ƒ LEDs served to show status of central processing unit (CPU) 11 of 164 History of GaP red and green LEDs ƒ There are direct-gap and indirect-gap semiconductors ƒ GaAs is direct but GaP is indirect ƒ Iso-electronic impurities (such as N and Zn-O) enable light emission 12 of 164 6 Red GaP LEDs ƒ N results in green emission ƒ Zn-O results in red emission ƒ However, efficiency is limited 13 of 164 Application for GaP:N green LEDs ƒ Dial pad illumination ƒ Telephone company (AT&T) decided that green is better color than red 14 of 164 7 LEDs in calculators ƒ LEDs were used in first generation of calculators ƒ Displayed numbers could not be seen in bright daylight ƒ LEDs consumed so much power that all calculators had rechargeable batteries 15 of 164 History of GaN blue, green, and white light emitters ƒ Blue emission in GaN in 1972, Maruska et al., 1972 ƒ However, no p-doping attained ƒ Devices were developed by RCA for three-color flat-panel display applications to replace cathode ray tubes (CRTs) ƒ Nichia Corporation (Japan) was instrumental in blue LED development ƒ Dr. Shuji Nakamura lead of development 16 of 164 8 Applications of green LEDs ƒ High-brightness LEDs for outdoor applications 17 of 164 History of AlGaInP visible LEDs ƒ Hewlett-Packard Corporation and Toshiba Corporation developed first high-brightness AlGaInP LEDs ƒ AlGaInP suited for red, orange, yellow, and yellow-green emitters 18 of 164 9 Recent applications Î High power applications 19 of 164 Radiative and nonradiative recombination ƒ Recombination rate is proportional to the product of the concentrations of electrons and holes ƒ R = B n p where B = bimolecular recombination coefficient n = electron concentration p = hole concentration 20 of 164 10

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