Title :
p-i-n MgBeZnO-Based Heterostructured Ultraviolet LEDs
Author :
Hsin-Ying Lee ; Hao-Yu Chang ; Li-Ren Lou ; Ching-Ting Lee
Author_Institution :
Dept. of Photonics, Nat. Cheng Kung Univ., Tainan, Taiwan
Abstract :
Triple targets of MgO, Be, and Zn and double targets of MgO and Al-doped ZnO were used to deposit i-Mg0.047Be0.083Zn0.870O films and n-MgZnO:Al films in a magnetron radio frequency co-sputter system. The optical energy bandgap of the i-Mg0.047Be0.083Zn0.870O films and n-MgZnO:Al films were 3.51 and 3.75 eV, respectively. The electron concentration and mobility of the n-MgZnO:Al films were 5.10 × 1021 cm-3 and 2.30 cm2/V·s, respectively. The i-Mg0.047Be0.083Zn0.870O film and n-MgZnO:Al films were sequentially deposited on a p-GaN layer for fabricating p-i-n ultraviolet light-emitting diode heterostructures. The peak emission wavelength of the resulting ultraviolet light-emitting diodes was ranging from 352.8 to 362.6 nm, when the injection current increased from 5 to 80 mA.
Keywords :
II-VI semiconductors; III-V semiconductors; aluminium; beryllium compounds; electron density; electron mobility; gallium compounds; light emitting diodes; magnesium compounds; optical fabrication; semiconductor thin films; sputter deposition; thin film devices; wide band gap semiconductors; zinc compounds; GaN-Mg0.047Be0.083Zn0.870O-MgZnO:Al; electron concentration; electron mobility; emission wavelength; injection current; magnetron radio frequency cosputter system; optical energy bandgap; p-i-n heterostructured ultraviolet LED; p-i-n ultraviolet light-emitting diode heterostructures; thin films; Light emitting diodes; Optical films; Photonic band gap; Radio frequency; Zinc oxide; Al doped-MgZnO; MgBeZnO active layer; bandgap modultion; deep UV LEDs;
Journal_Title :
Photonics Technology Letters, IEEE
DOI :
10.1109/LPT.2013.2275195
