Effect of Strain in Channel on Electron Transport Properties of Ga_1−xIn_xSb High Electron Mobility Transistor Structures with Strained‐Al_0.40In_0.60Sb/Al_0.25In_0.75Sb Stepped Buffer

Abstract: GaInSb is one of the attractive Sb‐based channel materials for high electron mobility transistors (HEMTs) that can operate in the terahertz band. The effect of strain in the channel on the electron transport properties of Ga1−x In x Sb channel HEMT structures (x = 0.60, 0.78, 0.85, 0.90, and 0.94) with the strained‐Al0.40In0.60Sb/Al0.25In0.75Sb stepped buffer is investigated. The strain in the Ga1−x In x Sb channel layer is determined by the lattice constant of Al0.25In0.75Sb lower buffer layer. The electron m… Show more

“…And the band gap can be increased from 0.18 eV (InSb) to 0.725 eV (GaSb) [4,5], and the cutoff wavelength can be adjusted from 1.7 μm (GaSb) to 7.3 μm (InSb) [6]. Therefore, GaInSb crystals can be more widely used in epitaxial substrate materials [7], quantum well lasers [8], high electron mobility transistors [9], thermoelectric materials [10,11], as well as infrared (IR) and near-infrared (NIR) devices [12][13][14][15] and other fields.…”

Improving the quality and properties of GaInSb crystal with Al doping

“…And the band gap can be increased from 0.18 eV (InSb) to 0.725 eV (GaSb) [4,5], and the cutoff wavelength can be adjusted from 1.7 μm (GaSb) to 7.3 μm (InSb) [6]. Therefore, GaInSb crystals can be more widely used in epitaxial substrate materials [7], quantum well lasers [8], high electron mobility transistors [9], thermoelectric materials [10,11], as well as infrared (IR) and near-infrared (NIR) devices [12][13][14][15] and other fields.…”

Improving the quality and properties of GaInSb crystal with Al doping

Effect of the Maximum Furnace Temperature on the Growth Process of Gainsb Crystals