Dislocation characterization of GaN layers in high-performance, High-Electron-Mobility Transistor structures grown on on-axis and off-axis 4H-SiC(0001) substrates
Seung Min Lee , Woon Jae Ruh , Hyun Jin Choi , Da Mi Kwon , Eun Ah Cheon , Minhyuk Choi , Young-Kyun Noh , Mino Yang , Seungwoo Song , Young Heon Kim
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引用次数: 0
Abstract
Controlling the dislocation behavior in component layers is critical for fabricating high-performance, high-electron-mobility transistor (HEMT) devices. The dislocation characteristics in the gallium nitride (GaN) layers of HEMT structures grown on on-axis and off-axis 4H-SiC substrates via molecular beam epitaxy were studied using various X-ray diffraction (XRD) and transmission electron microscopy (TEM) techniques. By employing high-resolution XRD and two-beam bright-field TEM images, the dislocation densities could be quantitatively analyzed, and the type of dislocations was identified in the GaN layers; the dislocation density on the off-axis substrate was higher than that on the on-axis substrate under the same deposition conditions, with a relative increase in the screw- and mixed-type dislocations identified in the GaN layer on the off-axis substrate. The evolution of screw- and mixed-type dislocations in an AlN buffer layer was also evident on the off-axis 4H-SiC substrate. Finally, the origin of the screw- and mixed-type dislocations was briefly demonstrated based on the atomic structures of the surface step of the off-axis 4H-SiC substrate. These findings provide valuable insights into the dislocation dynamics in GaN layers grown onto misoriented SiC substrates, contributing to the global effort to achieve superior HEMT performance through the optimization of epitaxial growth strategies.
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Materials Science in Semiconductor Processing provides a unique forum for the discussion of novel processing, applications and theoretical studies of functional materials and devices for (opto)electronics, sensors, detectors, biotechnology and green energy.
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Coverage will include: advanced lithography for submicron devices; etching and related topics; ion implantation; damage evolution and related issues; plasma and thermal CVD; rapid thermal processing; advanced metallization and interconnect schemes; thin dielectric layers, oxidation; sol-gel processing; chemical bath and (electro)chemical deposition; compound semiconductor processing; new non-oxide materials and their applications; (macro)molecular and hybrid materials; molecular dynamics, ab-initio methods, Monte Carlo, etc.; new materials and processes for discrete and integrated circuits; magnetic materials and spintronics; heterostructures and quantum devices; engineering of the electrical and optical properties of semiconductors; crystal growth mechanisms; reliability, defect density, intrinsic impurities and defects.
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