Title :
Effective Thermal Management in Ultraviolet Light-Emitting Diodes With Micro-LED Arrays
Author :
Lobo Ploch, N. ; Rodriguez, Horacio ; Stolmacker, C. ; Hoppe, Michael ; Lapeyrade, M. ; Stellmach, J. ; Mehnke, Frank ; Wernicke, T. ; Knauer, A. ; Kueller, Viola ; Weyers, M. ; Einfeldt, S. ; Kneissl, M.
Author_Institution :
Inst. of Solid State Phys., Tech. Univ. of Berlin, Berlin, Germany
Abstract :
We report on the use of micro-LED arrays, consisting of a matrix of interconnected micrometer-size light-emitting diodes (LEDs), to ensure uniform current injection, reduced series resistance, and improved heat extraction in LEDs emitting in the ultraviolet wavelength region. With the help of experiments and simulations, we show that, in both 380- and 300- to 325-nm LEDs, a greater than twofold decrease in the thermal resistance of the device, as compared with a conventional large area contact, is possible with the use of micro-LED arrays. The thermal resistance was found to linearly decrease with the size of the individual micro-LED, indicating that the improved heat dissipation is mainly due to the division of the heat source from one large area for the square contact into smaller pixels, thus allowing a sufficient area for the dissipation of the generated heat.
Keywords :
cooling; light emitting diodes; current injection; heat dissipation; heat extraction; heat source; interconnected micrometer-size light emitting diodes; microLED arrays; series resistance; thermal management; thermal resistance; ultraviolet light-emitting diodes; ultraviolet wavelength region; Current measurement; Geometry; Light emitting diodes; Resistance heating; Thermal resistance; InAlGaN; micro-LED arrays; thermal management; ultraviolet (UV) light-emitting diodes (LEDs);
Journal_Title :
Electron Devices, IEEE Transactions on
DOI :
10.1109/TED.2012.2234462
