Title :
High Efficiency GaN Light-Emitting Diodes With Two Dimensional Photonic Crystal Structures of Deep-Hole Square Lattices
Author :
Shin, Young Chul ; Kim, Dong Ho ; Kim, Eun Hong ; Park, Joong-Mok ; Ho, Kai-Ming ; Constant, Kristen ; Choe, Jong Ho ; Park, Q. Han ; Ryu, Han-Youl ; Baek, Jong Hyeob ; Jung, Tak ; Kim, Tae Geun
Author_Institution :
Sch. of Electr. Eng., Korea Univ., Seoul, South Korea
Abstract :
We report the enhanced light extraction of a square lattice photonic crystal GaN LED with a lattice constant of 460 nm and holes with a depth of 500 nm drilled through InGaN/GaN multiple quantum wells (MQWs) using laser holography and inductively coupled plasma reactive ion etching. In spite of the etching through the MQWs leading to undesirable surface recombination, the photonic crystal LEDs exhibited 1.37 times higher light extraction than that of the LEDs without photonic crystals at 20 mA. Theoretical studies using the 3-dimensional finite-difference time domain method show that the increase of the extraction efficiency with increasing etch depth is due to the increase of the density of the leaky modes into the air.
Keywords :
III-V semiconductors; finite difference time-domain analysis; gallium compounds; indium compounds; laser beam machining; lattice constants; light emitting diodes; photonic crystals; semiconductor quantum wells; sputter etching; surface recombination; wide band gap semiconductors; 3-dimensional finite-difference time domain method; InGaN-GaN; current 20 mA; deep-hole square lattices; depth 500 nm; extraction efficiency; inductively coupled plasma reactive ion etching; laser holography; lattice constant; leaky mode density; light extraction; light-emitting diodes; multiple quantum wells; square lattice photonic crystal LED; surface recombination; two dimensional photonic crystal structures; Etching; Gallium nitride; Holography; Laser theory; Lattices; Light emitting diodes; Optical coupling; Photonic crystals; Quantum well devices; Quantum well lasers; Finite-difference time domain method; light extraction efficiency; light-emitting diode; nitride-based semiconductor; photonic crystal;
Journal_Title :
Quantum Electronics, IEEE Journal of
DOI :
10.1109/JQE.2009.2030150
