The study of growth and characterization of Group III nitride semiconductor by RF Plasma-assisted Molecular Beam Epitaxy

Huang, Chih-Hao

25 June 2004

The group III nitride semiconductor grown on c-plane sapphire by radio frequency plasma assisted molecular beam epitaxy has been studied. To archive good quality GaN film, nitridation and low temperature buffer layer were applied to overcome the issue of lattice mismatch. Low temperature and long period nitridation process shows better improved of optical properties and crystal quality of GaN film. Buffer layer grown with slightly Ga-rich, substrate temperature at 522¢J, for 2 minutes leads to better GaN film. High substrate temperature and sufficient nitrogen to gallium ratio are two important factors to control the growth of the good quality GaN epilayer. Chemical etching and observation of surface reconstructions were used to characterize the polarity of group III nitrides. The Ga-polarity GaN film shows 2x surface reconstruction with high chemical resistance while the N-polarity is sensitive to chemical and displays the 3x reconstruction pattern. The process of indium incorporated with GaN is very sensitive to growth temperature. The indium content decreased with increasing the substrate temperature and also decreased along the growth direction. The N-polar GaN with an indium-facilitated growth technique was also studied. Upon the incorporation of indium during growth, the photoluminescence intensity and electron mobility of GaN has been enhanced by a factor of 15 and 6 respectively. The electron concentration drastically increases by several orders of magnitude. The biaxial strain of GaN film estimated with Micro-Raman technique reduces from 0.6729 to 0.5044GPa. The full-widths at half maximum of asymmetric (10-12) x-ray reflection which related to the density of overall threading dislocations increases from 593 to744 arcsec. In contrast, the symmetric (0002) reflection related only to threading dislocations having a non-zero c-component Burgers vectors reduces from 528 to 276 arcsec. The enhancement of GaN optical property is generally attributed to the reduction of non-zero c-component dislocations. The reduction in density is confirmed by cross-sectional transmission electron microscopy.

Nitrides

Molecular beam epitaxy

High-resolution X-ray diffraction

Transmission election microscopy

Photoluminescence

Gallium Nitride

球面収差補正用薄膜レンズを用いた走査透過電子顕微鏡の高分解能化に関する研究

日比野, 倫夫, 花井, 孝明, 杉山, せつ子, 下山, 宏

03 1900

科学研究費補助金 研究種目:試験研究 課題番号:61850069 研究代表者:日比野 倫夫 研究期間:1986-1987年度

電子レンズ

走査透過電子顕微鏡(STEM)

薄膜レンズ

球面収差

Electron lens

SN比

Foil Lend

分解能

Recolution

球面収差補正

電子プローブ

Shperical aberration

収差補正

Correction

Electron Probe