Title :
Optimized Thermal Management From a Chip to a Heat Sink for High-Power GaN-Based Light-Emitting Diodes
Author :
Horng, Ray-Hua ; Hong, Jhih-Sin ; Tsai, Yu-Li ; Wuu, Dong-Sing ; Chen, Chih-Ming ; Chen, Chia-Ju
Author_Institution :
Dept. of Electro-Opt. Eng., Nat. Cheng Kung Univ., Tainan, Taiwan
Abstract :
To improve heat dissipation of sapphire-based LEDs, we develop a new LED package with a dual heat spreader design. The first heat spreader is a cup-shaped copper sheet, which was directly contacted with sapphire to enhance heat dissipation of the chip itself. The second heat spreader is the die-bonding material of diamond-added AgSnCu solder and a high thermal conductive metal-core printed circuit board (MCPCB), where the conventional dielectric layer was replaced with a thin diamond-like layer. Characterization results demonstrate that the diamond-added composite solder is useful in reducing LED thermal resistance, thus avoiding the thermal accumulation phenomenon. In addition, a LED packaged on the new MCPCB exhibits smaller total thermal resistance and larger light output power.
Keywords :
III-V semiconductors; diamond; gallium compounds; heat sinks; light emitting diodes; printed circuits; sapphire; solders; thermal management (packaging); wide band gap semiconductors; AgSnCu; GaN; LED package; MCPCB; diamond-added composite solder; diamond-like layer; die-bonding material; heat dissipation; heat sink; heat spreader design; high-power light-emitting diodes; high-thermal conductive metal-core printed circuit board; sapphire-based LED; thermal accumulation phenomenon; thermal management optimization; thermal resistance; Conducting materials; Copper; Dielectric materials; Heat sinks; Inorganic materials; Light emitting diodes; Packaging; Sheet materials; Thermal management; Thermal resistance; Composite solder; light-emitting diodes (LEDs); thermal resistance;
Journal_Title :
Electron Devices, IEEE Transactions on
DOI :
10.1109/TED.2010.2053492
