A thin, flat and single crystal membrane on which to mount sensors is generally required for integration with electronics through standard silicon processing technology. We present an approach to producing single crystal membranes of germanium with in-built tensile strain, which serves to keep the membrane flat and ripple free, and demonstrate a 600 nm thick, free-standing 1 mm2 Ge membrane. We convert the fabrication technique into an integrated-circuit compatible wafer scale process to produce 60 nm thin membranes with large areas of 3.5 mm2. The single crystal Ge membrane provides an excellent platform for further epitaxial growth or deposition of material
Scanning X-ray micro-diffraction has been used as a non-destructive probe of the local crystalline q...
Scanning X-ray micro-diffraction has been used as a non-destructive probe of the local crystalline q...
Scanning X-ray micro-diffraction has been used as a non-destructive probe of the local crystalline q...
A thin, flat and single crystal membrane on which to mount sensors is generally required for integra...
A thin, flat and single crystal membrane on which to mount sensors is generally required for integra...
A thin, flat, and single crystal germanium membrane would be an ideal platform on which to mount sen...
A thin, flat, and single crystal germanium membrane would be an ideal platform on which to mount sen...
Under the terms of the Creative Commons Attribution (CC BY) license to their work.-- et al.A thin, f...
A thin, flat, and single crystal germanium membrane would be an ideal platform on which to mount sen...
Germanium membranes and microstructures of 50–1000 nm thickness have been fabricated by a combinatio...
Germanium membranes and microstructures of 50–1000 nm thickness have been fabricated by a combinatio...
Germanium membranes and microstructures of 50–1000 nm thickness have been fabricated by a combinatio...
Germanium membranes and microstructures of 50-1000 nm thickness have been fabricated by a combinatio...
Bi-axially strained Germanium (Ge) is an ideal material for Silicon (Si) compatible light sources, o...
We deposited Ge layers on (001) Si substrates by molecular beam epitaxy and used them to fabricate s...
Scanning X-ray micro-diffraction has been used as a non-destructive probe of the local crystalline q...
Scanning X-ray micro-diffraction has been used as a non-destructive probe of the local crystalline q...
Scanning X-ray micro-diffraction has been used as a non-destructive probe of the local crystalline q...
A thin, flat and single crystal membrane on which to mount sensors is generally required for integra...
A thin, flat and single crystal membrane on which to mount sensors is generally required for integra...
A thin, flat, and single crystal germanium membrane would be an ideal platform on which to mount sen...
A thin, flat, and single crystal germanium membrane would be an ideal platform on which to mount sen...
Under the terms of the Creative Commons Attribution (CC BY) license to their work.-- et al.A thin, f...
A thin, flat, and single crystal germanium membrane would be an ideal platform on which to mount sen...
Germanium membranes and microstructures of 50–1000 nm thickness have been fabricated by a combinatio...
Germanium membranes and microstructures of 50–1000 nm thickness have been fabricated by a combinatio...
Germanium membranes and microstructures of 50–1000 nm thickness have been fabricated by a combinatio...
Germanium membranes and microstructures of 50-1000 nm thickness have been fabricated by a combinatio...
Bi-axially strained Germanium (Ge) is an ideal material for Silicon (Si) compatible light sources, o...
We deposited Ge layers on (001) Si substrates by molecular beam epitaxy and used them to fabricate s...
Scanning X-ray micro-diffraction has been used as a non-destructive probe of the local crystalline q...
Scanning X-ray micro-diffraction has been used as a non-destructive probe of the local crystalline q...
Scanning X-ray micro-diffraction has been used as a non-destructive probe of the local crystalline q...