[1] B. Bowers Lengthening the Day: a History of Lighting Technology, Oxford University Press, UK, 1998

[2] D. DeLaura A brief history of lighting, Opt. Photonics News ( September 2008 ), p. 23

[3] R. Fouquet; P.J.G. Pearson Seven centuries of energy services: the price and use of light in the United Kingdom (1300–2000), Energy J., Volume 27 (2006), p. 139

[4] History of street lighting http://www.historyoflighting.net/electric-lighting-history/history-of-street-lighting/ (available at)

[5] M.G. Craford From Holonyak to today, Proc. IEEE, Volume 101 (2013), p. 2170

[6] J.Y. Tsao; J.J. Wierer; L.E.S. Rohwer; M.E. Coltrin; M.H. Crawford; J.A. Simmons; P.-C. Hung; H. Saunders; D.S. Sizov; R. Bhat; C.-E. Zah Ultra-efficient solid-state lighting: likely characteristics, economic benefits, technological approaches (T.-Y. Seong et al., eds.), III – Nitride Based Light Emitting Diodes and Applications, Top. Appl. Phys., vol. 133, Springer, Dordrecht, The Netherlands, 2017, p. 11

[7] J.Y. Tsao; H.D. Saunders; J.R. Creighton; M.E. Coltrin; J.A. Simmons Solid-state lighting: an energy-economics perspective, J. Phys. D, Appl. Phys., Volume 43 (2010)

[8] The History of Stage and Theatre Lighting, The Edison Electric Illuminating Company of Boston, 1929

[9] Anon The Welsbach Light, Science (N.S.), Volume 12 (1900) no. 312, p. 951

[10] E. Baumgartner Carl Auer von Welsbach: a pioneer in the industrial application of rare earths (C.H. Evans, ed.), Episodes from the History of the Rare Earth Elements, Kluwer, 1996, p. 113

[11] V. Gutmann More light: a short historical sketch of Carl Auer von Welsbach, J. Chem. Educ., Volume 47 (1970), p. 209

[12] E. Furuta; Y. Yoshizawa; T. Aburai Comparisons between radioactive and non-radioactive gas lantern mantles, J. Radiol. Prot., Volume 20 (2000), p. 423

[13] H.F. Ivey Candoluminescence and radical-excited luminescence, J. Lumin., Volume 8 (1974), p. 271

[14] P. Alstone; A. Jacobson LED advances accelerate universal access to electric lighting, C. R. Physique, Volume 19 (2018), pp. 146-158 ( in this issue )

[15] T. Bauer Thermophotovoltaics: Basic Principles and Critical Aspects of System Design, Springer, Berlin, Heidelberg, 2011

[16] P. Aigrain, Thermophotovoltaic conversion of radiant energy (unpublished lecture series at MIT), 1956.

[17] T.J. Coutts A review of progress in thermophotovoltaic generation of electricity, Renew. Sustain. Energy Rev., Volume 3 (1999), p. 77

[18] R.E. Nelson Thermophotovoltaic emitter development, AIP Conf. Proc., Volume 321 (1995), p. 80

[19] O. Ilic; P. Bermel; G. Chen; J.D. Joannopoulos; I. Celanovic; M. Soljačić Tailoring high-temperature radiation and the resurrection of the incandescent source, Nat. Nanotechnol., Volume 11 (2016), p. 320

[20] O. Ilic Tailoring thermal radiation through light recycling http://www.its.caltech.edu/~ilic/recycling-light/ (retrieved at)

[21] J.F. Waymouth Handbook of Advanced Lighting Technology (R. Karlicek et al., eds.), Springer International Publishing, Switzerland, 2017, p. 3 (For an excellent review of electrical lighting, see History of light sources)

[22] DOE, Energy savings forecast of solid-state lighting in general illumination applications, 2016, available at: https://energy.gov/sites/prod/files/2016/09/f33/energysavingsforecast16_2.pdf.

[23] M.F. Gendre Handbook of Advanced Lighting Technology (R. Karlicek et al., eds.), Springer International Publishing, Switzerland, 2017, p. 1013 (For an excellent review of incandescent lamps, see Incandescent lamps)

[24] G. Lister, Electrodeless lamps and UV sources, ibid., 1141.

[25] H.J. Round A note on carborundum, Electron. World, Volume 47 (1907), p. 308

[26] J.-M. Dilhac; E. Branly The Coherer, and the Branly effect, IEEE Commun. Mag. ( September 2009 ), p. 20

[27] H.F. Ivey Electroluminescence seen in 1907, Science, Volume 164 (1969), p. 1342

[28] O.V. Losev, Detector–generator. Detector–amplifier, TiTbp, June 1922, pp. 374–386 (in Russian).

[29] O. Lossev Oscillating crystals, Wireless World Radio Rev. ( 22 October 1924 ), p. 93

[30] O.V. Lossev Luminous carborundum detector and detection effect and oscillations with crystals, Philos. Mag., Volume 7 (1928), p. 1024

[31] C. Hilsum Light from semiconductors, New Sci., Volume 20 (1963) no. 12, p. 666

[32] O.W. Lossew Anwendung der Quantentheorie zur Leuchtenerscheinung, Phys. Z., Volume 30 (1929), p. 920

[33] A.H. Wilson The theory of electronic semi-conductors, Proc. R. Soc. Lond. Ser. A, Volume 133 (1931), p. 458

[34] O.W. Lossew Uber den Lichtelektrischen Effekt in besonderen activen Schicht der Karborundum Krystalle, Phys. Z., Volume 34 (1933), p. 397

[35] O.V. Losev Spectral distribution of the rectifying effect in single crystals of carborundum, Dokl. Akad. Nauk SSSR, Volume 29 (1940), p. 363

[36] E.O. Loebner Subhistories of the light emitting diode, IEEE Trans. Electron Devices, Volume ED-23 (1976), p. 675

[37] M.A. Novikov Oleg Vladimirovich Losev: pioneer of semiconductor electronics (celebrating one hundred years since his birth), Phys. Solid State, Volume 1 (2004), p. 46

[38] N. Zheludev The life and times of the LED — a 100-year history, Nat. Photonics, Volume 1 (2007), p. 189

[39] T. Figielski; A. Torun On the origin of light emitted from reverse biased p–n junctions, Exeter, UK, Inst. Phys., London (1962), p. 863

[40] T. Brazzini et al. Mechanism of hot electron electroluminescence in GaN-based transistors, J. Phys. D, Appl. Phys., Volume 49 (2016)

[41] R. Ostermeir; F. Koch; H. Brugger; P. Narozny; H. Dambkes Hot carrier light emission from GaAs HEMT devices, Semicond. Sci. Technol., Volume 7 (1992), p. B564

[42] G.M. Destriau Recherches sur les scintillations des sulfures de zinc aux rayons α, J. Chim. Phys., Volume 33 (1936), p. 620

[43] S.P. David; R. Gaume Electroluminescent thin film phosphors (B.K. Moorthy, ed.), Thin Film Structures in Energy Applications, Springer International Publishing, Switzerland, 2015, p. 243

[44] A.N. Krasnov Electroluminescent displays: history and lessons learned, Displays, Volume 24 (2003), p. 73

[45] M. Bredol; H. Schulze Dieckhoff Materials for powder-based AC-electroluminescence, Materials, Volume 3 (2010), p. 1353

[46] P.F. Smet; I. Moreels; Z. Hens; D. Poelman Luminescence in sulfides: a rich history and a bright future, Materials, Volume 3 (2010), p. 2834

[47] G.M. Destriau; H.F. Ivey Electroluminescence and related topics, Proc. Inst. Radio Eng., Volume 43 (1955), p. 1911

[48] A.G. Fischer Injection electroluminescence, Solid-State Electron., Volume 2 (1961), p. 232

[49] P.J. Dean Comparisons and contrasts between light emitting diodes and high field electroluminescent devices, J. Lumin., Volume 23 (1981), p. 17

[50] P.J. Dean Junction electroluminescence (R. Wolfe, ed.), Applied Solid State Science, vol. 1, Academic Press, New York, London, 1969, p. 2

[51] G.M. Destriau The new phenomenon of electrophotoluminescence and its possibilities for the investigation of crystal lattice, Philos. Mag. Ser. 7, Volume 38 (1947), p. 700

[52] A.H. Wilson The theory of electronic semi-conductors II, Proc. R. Soc. Lond. Ser. A, Volume 134 (1931), p. 277

[53] M. Riordan; L. Hoddeson The origins of the pn junction, IEEE Spectr., Volume 34 (1997), p. 46

[54] K. Lehovec; C.A. Accardo; E. Jamgochian Injected light emission of silicon carbide crystals, Phys. Rev., Volume 83 (1951), p. 603

[55] A. Van Dormael The ‘French’ transistor, Proceedings of the 2004 IEEE Conference on the History of Electronics, Bletchley Park, England, June 2004 http://www.cdvandt.org/VanDormael.pdf (available at)

[56] M. Riordan How Europe missed the transistor, IEEE Spectr. ( November 2005 ), p. 47

[57] B. Lojek History of Semiconductor Engineering, Springer, Berlin, 2007

[58] K. Lehovec; C.A. Accardo; E. Jamgochian Light emission produced by current injected into a green silicon-carbide crystal, Phys. Rev., Volume 89 (1953), p. 20

[59] J.R. Haynes; H.B. Briggs Radiation produced in germanium and silicon by electron–hole recombination, Phys. Rev., Volume 86 (1952), p. 647

[60] R.D. Dupuis; M.R. Krames History, development, and applications of high-brightness visible light-emitting diodes, J. Lightwave Technol., Volume 26 (2008), p. 1154

[61] R. Braunstein Radiative transitions in semiconductors, Phys. Rev., Volume 99 (1955), p. 1892

[62] R.J. Keyes; T.M. Quist Recombination radiation emitted by gallium arsenide, Proc. IRE, Volume 50 (1962), p. 1822

[63] M.R. Krames et al. Status and future of high-power light-emitting diodes for solid-state lighting, J. Disp. Technol., Volume 3 (2007), p. 160

[64] C. Lalau-Keraly; L.Y. Kuritzky; M. Cochet; C. Weisbuch Ray tracing for light extraction efficiency (LEE) modeling in nitride LEDs (T.-Y. Seong et al., eds.), III-Nitride Based Light Emitting Diodes and Applications, Springer Netherlands, Dordrecht, The Netherlands, 2013, p. 231

[65] R.J. Keyes (Festkörperprobleme/Advances in Solid State Physics), Volume vol. 7, Springer, Berlin, Heidelberg (1967), p. 217

[66] C. Hilsum The GaAs scene in 1962: the battle with Si, Semicond. Sci. Technol., Volume 28 (2013)

[67] R.D. Dupuis An introduction to the development of the semiconductor laser, IEEE J. Quantum Electron., Volume 23 (1987), p. 651

[68] H.G. Grimmeiss; J.W. Allen Light emitting diodes – how it started, J. Non-Cryst. Solids, Volume 352 (2006), p. 871

[69] J.W. Allen; H.G. Grimmeiss Visible light-emitting diodes – the formative years, Mater. Sci. Forum, Volume 590 (2008), p. 1

[70] M. Gershenzon Electroluminescence from p–n junctions in semiconductors (P. Goldberg, ed.), Luminescence of Inorganic Solids, Academic Press, New York, 1966, p. 603

[71] E.F. Schubert Light Emitting Diodes, Cambridge University Press, 2006

[72] J.W. Allen; P.E. Gibbons Gallium phosphide diodes for the production of fast light pulses, Nucl. Instrum. Methods, Volume 14 (1961), p. 355

[73] J.W. Allen Firsts for LEDs, Phys. World ( September 2005 ), p. 20

[74] G.A. Wolff; R.A. Hebert; J.D. Broder, Polytechnic Institute of Brooklyn ( Sept. 1955 ), pp. 9-10 (unpublished)

[75] G.A. Wolff, R.A. Hebert, J.D. Broder, Recent investigations on the electroluminescence of gallium phosphide, in: M. Schön, H. Welker (Eds.), Vorträge des Internationalen Kolloquiums 1956 “Halbleiter und Phosphore” in Garmisch-Partenkirchen, Germany, Halbleiter und Phosphore/Semiconductors and Phosphors/Semiconducteurs et Phosphores. Vieweg+Teubner Verlag, Wiesbaden, Germany, p. 547.

[76] N. Holonyak; D.C. Jillson; S.F. Bevacqua Halogen vapor transport and growth of epitaxial layers of intermetallic compounds and compound mixtures (J.B. Schroeder, ed.), Metallurgy of Semiconductor Materials, vol. 15, Interscience, New York, 1962, pp. 49-59

[77] N. Holonyak; S.F. Bevacqua Coherent (visible) light emission from GaAs_1−xP_x junctions, Appl. Phys. Lett., Volume 1 (1962), p. 82

[78] H. Manchester, Light of hope – or terror? Readers Digest (February 1963) 97.

[79] H.G. Grimmeiss; H. Scholz Efficiency of recombination radiation in GaP, Phys. Lett., Volume 8 (1964), p. 233

[80] D. Feezell; S. Nakamura Invention, development, and status of the blue light-emitting diode, the enabler of solid-state lighting, C. R. Physique, Volume 19 (2018), pp. 113-133 ( in this issue )

[81] J.J. Wierer; J.Y. Tsao; D.S. Sizov The potential of III-nitride laser diodes for solid-state lighting, Phys. Status Solidi C, Volume 11 (2014), p. 674

[82] A. Neumann; J.J. Wierer; W. Davis; Y. Ohno; S.R.J. Brueck; J.Y. Tsao Four-color laser white illuminant demonstrating high color rendering quality, Opt. Express, Volume 19 (2011), p. A982

[83] Anon The early history of gallium nitride research http://www.compoundsemi.com/the-early-history-of-gallium-nitride-research/ (retrieved at)

[84] C. Weyrich Light emitting diodes for the visible spectrum, Festkörperprobleme/Advances in Solid State Physics, vol. 18, Springer, Berlin, Heidelberg, 1978, p. 265

[85] C.J. Nuese; H. Kressel; I. Ladany Light-emitting diodes and semiconductor materials for displays, J. Vac. Sci. Technol., Volume 10 (1973), p. 772

[86] A.A. Bergh; P.J. Dean Light-emitting diodes, Proc. IEEE, Volume 6 (1972), p. 156

[87] M.G. Craford LEDs challenge the incandescents, IEEE Circuits Devices Mag. ( 24 September 1992 )

[88] M. Shur; R. Gaska Deep-ultraviolet light-emitting diodes, IEEE Trans. Electron Devices, Volume 57 (2010), p. 121

[89] F.M. Steranka et al. Red AlGaAs light-emitting diodes, Hewlett-Packard J. ( August 1988 ), p. 84

[90] A.A. Bergh; P.J. Dean Light Emitting Diodes, Oxford University Press, 1976

[91] G.B. Stringfellow Materials issues in high brightness light emitting diodes (G.B. Stringfellow; M.G. Craford, eds.), High Brightness Light Emitting Diodes, Academic Press, San Diego, CA, USA, 1997, p. 1

[92] V.A. Mishurnyi et al. Growth of quantum-well heterostructures by liquid phase epitaxy, Crit. Rev. Solid State Mater. Sci., Volume 31 (2006), p. 1

[93] M. Fukuda Reliability and Degradation in Semiconductor Lasers and LEDs, Artech House, Boston, London, 1991

[94] J.W. Matthews; A.E. Blakeslee Defects in epitaxial multilayers, J. Cryst. Growth, Volume 27 (1974), p. 118

[95] G. Lasher; F. Stern Spontaneous and stimulated recombination radiation in semiconductors, Phys. Rev., Volume 133 (1946), p. A553

[96] C. Weisbuch; R.C. Miller; R. Dingle; A.C. Gossard; W. Wiegmann Intrinsic radiative recombination from quantum states in GaAs–AlGaAs multi-quantum well structures, Solid State Commun., Volume 37 (1981), p. 219

[97] B. Deveaud; F. Clérot; N. Roy; K. Satzke; B. Sermage; D.S. Katzer Enhanced radiative decay of free excitons in GaAs quantum wells, Phys. Rev. Lett., Volume 67 (1991), p. 2355

[98] C. Weisbuch; H. Benisty; R. Houdré Overview of fundamentals and applications of electrons, excitons and photons in confined structures, J. Lumin., Volume 85 (2000), p. 271

[99] I. Galbraith; S.W. Koch A comparison of lasing mechanisms in ZnSe and GaAs, J. Cryst. Growth, Volume 159 (1996), p. 667

[100] M. Kira; F. Jahnke; S.W. Koch Microscopic theory of excitonic signatures in semiconductor photoluminescence, Phys. Rev. Lett., Volume 81 (1998), p. 3263

[101] J. Szczytko; L. Kappei; F. Morier-Genoud; T. Guillet; M.T. Portella-Oberli; B. Deveaud Excitons or free carriers? That is the question, Phys. Status Solidi C, Volume 1 (2004), p. 493

[102] Z.I. Alferov; V.M. Andreev; E.L. Portnoi; M.K. Trukan AlAs-GaAs heterojunction injection lasers with a low room-temperature threshold, Fiz. Tekh. Poluprov., Volume 3 (1969), p. 1328

[103] I. Hayashi; M.B. Panish; P.W. Foy; S. Sumski Junction lasers which operate continuously at room temperature, Appl. Phys. Lett., Volume 17 (1970), p. 109

[104] J.J. Coleman The development of the semiconductor laser diode after the first demonstration in 1962, Semicond. Sci. Technol., Volume 27 (2012)

[105] S. Strite The III–V Nitride Semiconductors for blue light emission: recent progress and a critical evaluation of their potential in comparison to the ZnSe based II–VI semiconductors, Festkörperprobleme/Advances in Solid State Physics, vol. 34, Springer, Berlin, 1994, p. 79

[106] H.G. Grimmeiss; H. Koelmans Uber die Kantenemission und Andere Emissionen des GaN, Z. Naturforsch. A, Volume 14 (1959), p. 264

[107] H.G. Grimmeiss; H. Koelmans Lumineszenz- und Photoleitungseigenschaften von dotiertem GaN, Z. Naturforsch. A, Volume 15 (1960), p. 799

[108] H.P. Maruska; J.J. Tietjen The preparation and properties of vapor-deposited single-crystalline GaN, Appl. Phys. Lett., Volume 15 (1969), p. 327

[109] H.P. Maruska; W.C. Rhines A modern perspective on the history of semiconductor nitride blue light sources, Solid-State Electron., Volume 111 (2015), p. 32

[110] R. Dingle; D.D. Sell; S.E. Stokowski; M. Ilegems Absorption, reflectance, and luminescence of GaN epitaxial layers, Phys. Rev. B, Volume 4 (1971), p. 1211

[111] R. Dingle; K.L. Shaklee; R.F. Leheny; R.B. Zetterstrom Stimulated emission and laser action in gallium nitride, Appl. Phys. Lett., Volume 19 (1971), p. 5

[112] M. Ilegems; H.C. Montgomery Electrical properties of n-type vapor-grown gallium nitride, J. Phys. Chem. Solids, Volume 34 (1973), p. 885

[113] S. Nakamura; M.R. Krames History of gallium–nitride-based light-emitting diodes for illumination, Proc. IEEE, Volume 101 (2012), p. 2211

[114] H. Amano Progress and prospect of growth of wide-band-gap group III nitrides (T.-Y. Seong et al., eds.), III-Nitride Based Light Emitting Diodes and Applications, Springer Netherlands, Dordrecht, The Netherlands, 2013, p. 1

[115] M. Stavola Hydrogen passivation in semiconductors, Acta Phys. Pol. A, Volume 82 (1992), p. 585

[116] A. David; M.J. Grundmann Influence of polarization fields on carrier lifetime and recombination rates in InGaN-based light-emitting diodes, Appl. Phys. Lett., Volume 97 (2010)

[117] A.E. Romanov; E.C. Young; F. Wu; A. Tyagi; C.S. Gallinat; S. Nakamura; S.P. DenBaars; J.S. Speck Basal plane misfit dislocations and stress relaxation in III-nitride semipolar heteroepitaxy, J. Appl. Phys., Volume 109 (2011)

[118] M. Pattison; M. Hansen; J.Y. Tsao C. R. Physique, 19 (2018), pp. 134-145 ( in this issue )

[119] Committee on Optical Science and Engineering; National Research Council Optical Science and Engineering for the 21st Century, National Academies Press, 1998

[120] R. Haitz; J.Y. Tsao Solid-state lighting: ‘the case’ 10 years after and future prospects, Phys. Status Solidi A, Volume 208 (2011), p. 17

[121] M. Pope; H.P. Kallmann; P. Magnante Electroluminescence in organic crystals, J. Chem. Phys., Volume 38 (1963), p. 2042

[122] W. Helfrich; W.G. Schneider Recombination radiation in anthracene crystals, Phys. Rev. Lett., Volume 14 (1965), p. 229

[123] C.W. Tang; S.A. VanSlyke Organic electroluminescent diodes, Appl. Phys. Lett., Volume 51 (1987), p. 913

[124] J.H. Burroughes; D.D.C. Bradley; A.R. Brown; R.N. Marks; K. Mackay; R.H. Friend; P.L. Burns; A.B. Holmes Light-emitting diodes based on conjugated polymers, Nature (London), Volume 347 (1990), p. 539

[125] S. Reineke; M. Thomschke; B. Lüssem; K. Leo White organic light-emitting diodes: status and perspective, Rev. Mod. Phys., Volume 85 (2013), p. 1245

[126] M.-H. Lu; J.C. Sturm Optimization of external coupling and light emission in organic light-emitting devices: modeling and experiment, J. Appl. Phys., Volume 91 (2002), p. 595

[127] W. Brütting; J. Frischeisen; T.D. Schmidt; B.J. Scholz; C. Mayr Device efficiency of organic light-emitting diodes: progress by improved light outcoupling, Phys. Status Solidi A, Volume 210 (2013), p. 44

[128] DOE Solid-State Lighting 2017 Suggested Research Topics Supplement: Technology and Market Context, edited by James Brodrick, Ph.D; available at: https://energy.gov/sites/prod/files/2017/09/f37/ssl_supplement_suggested-topics_sep2017_0.pdf.

[129] A. David; L.A. Whitehead LED-based white light, C. R. Physique, Volume 19 (2018), pp. 169-181 ( in this issue )

[130] W.E. Bradley, Electronic cooling device and method for the fabrication thereof, US patent 2 898 743 (filed 23 July 23 1956).

[131] G.C. Dousmanis; C.W. Mueller; H. Nelson; K.G. Petzinger Evidence of refrigerating action by means of photon emission in semiconductor diodes, Phys. Rev., Volume 133 (1964), p. A316

[132] P. Lenard; F. Schmidt; R. Tomaschek, Akademische Verlag, Leipzig (1928), p. 9461

[133] P. Pringsheim Zwei Bemerkungen über den Unterschied von Lumineszenz- und Temperaturstrahlung, Z. Phys., Volume 57 (1929), p. 739

[134] S. Vavilov Some remarks on the Stokes law, J. Phys. (USSR), Volume 9 (1945), p. 68

[135] P. Pringsheim Some remarks concerning the difference between luminescence and temperature radiation, anti-Stokes fluorescence, J. Phys. (USSR), Volume 10 (1946), p. 495

[136] S. Vavilov Photoluminescence and thermodynamics, J. Phys. (USSR), Volume 10 (1946), p. 499

[137] L. Landau On the thermodynamics of photoluminescence, J. Phys. (USSR), Volume (Moscow)10 (1946), p. 503

[138] J.J. Hopfield Aspects of polaritons, J. Phys. Soc. Jpn., Suppl., Volume 21 (1966), p. 77

[139] C. Weisbuch; H. Benisty; R. Houdré Overview of fundamentals and applications of electrons, excitons and photons in confined structures, J. Lumin., Volume 85 (2000), p. 271

[140] C. Weisbuch; N. Nishioka; A. Ishikawa; Y. Arakawa Observation of the coupled exciton–photon mode splitting in a semiconductor quantum microcavity, Phys. Rev. Lett., Volume 69 (1992), p. 3314

[141] R.P. Stanley; R. Houdré; C. Weisbuch; U. Oesterle; M. Ilegems Cavity-polariton photoluminescence in semiconductor microcavities: experimental evidence, Phys. Rev. B, Volume 53 (1996)

[142] A. Kastler Quelques suggestions concernant la production optique et la détection optique d'une inegalité de population des niveaux de quantification spatiale des atomes. Application à l'experience de Stern et Gerlach et à la résonance magnétique, J. Phys. Radium, Volume 11 (1950), p. 255

[143] R.I. Epstein; M.I. Buchwald; B.C. Edwards; T.R. Gosnell; C.E. Mungan Observation of laser-induced fluorescent cooling of a solid, Nature, Volume 377 (1995), p. 500

[144] P. Santhanam; D.J. Gray; R.J. Ram Thermoelectrically pumped light-emitting diodes operating above unity efficiency, Phys. Rev. Lett., Volume 108 (2012)

[145] L.Y. Kuritzky Epitaxy and Device Design for High Efficiency Blue LEDs and Laser Diodes, University of California, Santa Barbara, CA, USA, 2016 (Doctoral thesis)

[146] L.Y. Kuritzky, C. Weisbuch, J.S. Speck, Prospects for 100% wall-plug efficient III-nitride LEDs, unpublished.

[147] L.Y. Kuritzky; A.C. Espenlaub; B.P. Yonkee; C.D. Pynn; S.P. Denbaars; S. Nakamura; C. Weisbuch; J.S. Speck High wall-plug efficiency blue III-nitride LEDs designed for low current density operation, Opt. Express, Volume 25 (2017)

[148] J. Xue; Y. Zhao; S. Oh; J.S. Speck; S.P. Denbaars; S. Nakamura; R.J. Ram Thermally enhanced blue light-emitting diode, Appl. Phys. Lett., Volume 107 (2015)

[149] A. David; C.A. Hurni; N.G. Young; M.D. Craven Electrical properties of III-nitride LEDs: recombination-based injection model and theoretical limits to electrical efficiency and electroluminescent cooling, Appl. Phys. Lett., Volume 109 (2016)