This Phase I STTR effort will demonstrate intersubband quantum device modeling capability using UT-Dallas BandProf software package and optical coupling efficiency modeling using SMU optical cavity software packages. The software model will predict fabricated device characteristics based on data… More

This Phase II STTR effort will demonstrate intersubband and interband quantum device modeling capability using UT-Dallas BandProf software package and optical coupling efficiency modeling using SMU optical cavity software packages. The software model will predict fabricated device characteristics… More

This Phase I STTR proposes to develop Focal Plane Array (FPA) based on Corrugated-Infrared Hot Electron Transistor (C-IHET) technology as a passive sensor for discrimination seekers. The initial goal of achieving high sensitivity with operating temperature >77K for C-IHET in the 8 - 12 m LWIR… More

This Phase I SBIR effort will develop low dark-current and high radiation-hardness infrared detector technology based on unipolar barrier structure Type II strained-layer superlattices. The design architectures and process technologies developed to minimize dark current are expected to enhance… More

This Phase I SBIR effort will develop robust and high performance infrared detector technology based on two-color Type II strained-layer superlattices (SLS). The design architectures and process technologies in Sb-based SLS enable high-performance two-color LW/LW detectors. The SLS detector design… More

This Phase I SBIR effort will evaluate the preparation of epi-ready 211B InSb substrate to be used as starting substrate for the growth of high quality HgCdTe epi materials. The InSb substrate will be prepared via production III-V Molecular Beam Epitaxy (MBE) reactor. The 211B InSb substrate is… More

This Phase I SBIR effort will develop dual-band mid-wavelength infrared/long-wavelength infrared (MWIR/LWIR) detector technology based on dual monolithic type-II strained-layer superlattices (SLS). The dual-band detector will operate in either MWIR or LWIR mode depending on the applied voltage bias,… More

This Phase I SBIR effort will seek to develop high performance superlattice infrared focal plane array technology by establishing a 4"GaSb substrate manufacturing line based in Texas. Under this program, IntelliEPI proposes to develop 4"GaSb crystal pulling capability based on the… More

This Phase I SBIR effort will develop robust and high performance infrared detector technology based on GaSb-based Type II strained-layer superlattices (SLS). The advanced device design will be based on the Naval Research Lab (NRL) W-barrier and Ternary absorber epitaxy materials system. The… More