Title :
Quantum-Dot-Based Solid-State Lighting With Electric-Field-Tunable Chromaticity
Author :
Tsao, Jeffrey Y. ; Brener, Igal ; Kelley, D. ; Lyo, S.
Author_Institution :
Sandia Nat. Labs., Albuquerque, NM, USA
Abstract :
Solid-state lighting is currently based on blue light-emitting diodes combined with wavelength downconversion via phosphors. Replacing the phosphors with quantum dots has a number of potential advantages, including narrowband and size-tailorable emission spectra. Here, we point out another advantage: the ability to perform real-time tuning of chromaticity of solid-state lighting by altering quantum dot absorption or emission wavelengths and oscillator strengths using electric fields. We discuss a possible architecture for such a solid-state lamp, and the chromaticity ranges that could be obtained for given ranges of absorption or emission wavelength and oscillator strength changes.
Keywords :
light absorption; light emitting diodes; lighting; oscillator strengths; phosphors; quantum dots; real-time systems; P; blue light-emitting diodes; electric-field-tunable chromaticity; emission wavelength; narrowband emission spectra; oscillator strength changes; oscillator strengths; quantum dot absorption; quantum-dot-based solid-state lighting; real-time tuning; size-tailorable emission spectra; wavelength downconversion; Absorption; Color; Green products; Light emitting diodes; Rendering (computer graphics); Temperature distribution; Tuning; Chromaticity control; Stark effect; color temperature; light-emitting diode; liquid crystals; quantum dots; quantum yield; smart lighting; solid-state lighting; wavelength downconversion;
Journal_Title :
Display Technology, Journal of
DOI :
10.1109/JDT.2012.2225407
