Abstract
The stress evolution of GaN/AlN heterostructure grown on 6H-SiC substrate by plasma assisted molecular beam epitaxy (PA-MBE) has been studied. AlN nucleation layer and GaN layer were grown as a function of III/V ratio. GaN/AlN structure is found to form buried cracks when AlN is grown in the intermediate growth regime(III/V∼1)and GaN is grown under N-rich growth regime (III/V<1). The III/V ratio determines the growth mode of the layers that influences the lattice mismatch at the GaN/AlN interface. The lattice mismatch induced interfacial stress at the GaN/AlN interface relaxes by the formation of buried cracks in the structure. Additionally, the stress also relaxes by misorienting the AlN resulting in two misorientations with different tilts. Crack-free layers were obtained when AlN and GaN were grown in the N-rich growth regime (III/V<1) and metal rich growth regime (III/V≥1), respectively. AlGaN/GaN high electron mobility transistor (HEMT) heterostructure was demonstrated on 2-inch SiC that showed good two dimensional electron gas (2DEG) properties with a sheet resistance of 480 Ω/sq, mobility of 1280 cm2/V.s and sheet carrier density of 1×1013 cm−2.
Highlights
AlGaN/GaN high electron mobility transistor (HEMT) is an excellent candidate for high power, high frequency and high temperature device applications due to the superior properties of the GaN based material, such as wide bandgap energy, high breakdown field, high saturation velocity and high electron mobility
We investigate the effect of III/V ratio of both AlN and GaN on the stress evolution and cracking mechanism of GaN/AlN heterostructure grown on 6H-SiC substrate by plasma assisted molecular beam epitaxy (PA-MBE)
AlN nucleation layer for the samples in set A was grown on SiC substrate as a function of III/V ratio varying from the N-rich growth regime (III/V 1) similar to the studies performed on Si substrate.[11]
Summary
AlGaN/GaN high electron mobility transistor (HEMT) is an excellent candidate for high power, high frequency and high temperature device applications due to the superior properties of the GaN based material, such as wide bandgap energy, high breakdown field, high saturation velocity and high electron mobility. We investigate the effect of III/V ratio of both AlN and GaN on the stress evolution and cracking mechanism of GaN/AlN heterostructure grown on 6H-SiC substrate by plasma assisted molecular beam epitaxy (PA-MBE). This is followed by the demonstration of crack-free AlGaN/GaN HEMT heterostructure on 2-inch 6H-SiC substrate with good two-dimensional electron gas (2DEG) properties. The SiC substrate was subjected to ex-situ followed by in-situ cleaning for native oxide removal prior to the epitaxial growth It first underwent organic cleaning and a deionized (DI) water rinse. The full width at half maximum (FWHM) values were measured in an open detector configuration while the reciprocal space mapping (RSM) was performed using triple axis geometry
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