Prevalence of low back pain in emergency settings: a systematic review and meta-analysis

We have developed hydrogenated microcrystalline silicon germanium, which exhibits a red-shifted absorption spectrum relative to hydrogenated microcrystalline silicon, as a candidate material for the bottom cell of amorphous silicon-based tandem solar cells. Optical absorption, x-ray diffraction, and Raman scattering spectra are presented in addition to optoelectronic properties and light-induced changes.

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A study of the growth-mechanism and properties of microcrystalline silicon–germanium

Ganguly¹,

Fukawa²,

Ikeda³

et al. 1998

Journal of Non-Crystalline Solids

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In-Situ Monitoring of Surface Hydrogen on the a-SiGe:H Films

Toyoshima¹,

Ganguly²,

Ikeda³

et al. 1997

MRS Proc.

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The bonded hydrogen on the growing surface of hydrogenated amorphous silicon germanium (a-SiGe:H) alloy films has been investigated by use of infrared reflection absorption spectroscopy (IR-RAS). When the alloy films are Si-rich, the surface hydrogen bonded to Si atoms is found to behave in a similar way to those on the hydrogenated amorphous silicon (a-Si:H) films. This means that the thermal desorption stability of surface Si hydride species is not significantly affected by the coexistence of a small amount (typically 20 at.%) of Ge. On the contrary, the desorption behavior of surface hydrogen depends on the alloy composition when the a-SiGe:H films are Ge-rich. A surface reaction scheme is provided in an attempt to explain this series of behavior in surface hydrogen on the a-SiGe:H films.

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Microcrystalline Silicon Germanium: An Attractive Bottom-Cell Material for Thin-Film Silicon-Based Tandem-Solar-Cells

Ganguly¹,

Ikeda²,

Kajiwara³

et al. 1997

MRS Proc.

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We have prepared hydrogenated macrocrystalline silicon germanium by plasma enhanced CVD of a mixture of silane and germane gas diluted with hydrogen. The growth conditions have been systematically controlled to obtain large (∼400Å) crystallites of silicon-germanium as observed using Raman scattering and x-ray diffraction. The dangling bond (germanium) density has been reduced to <5×1016 cm−3 at low substrate temperatures (∼150°C). The optical absorption spectra of the 50% Ge containing material is red-shifted compared to microcrystalline silicon, consistent with a reduction of the indirect optical gap to 0.9eV. Schottky type cells fabricated using Au on an n+ crystalline silicon substrate confirm that the long wavelength response is remarkably enhanced in this material.

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T. Ikeda

Hydrogenated microcrystalline silicon germanium: A bottom cell material for amorphous silicon-based tandem solar cells

A study of the growth-mechanism and properties of microcrystalline silicon–germanium

In-Situ Monitoring of Surface Hydrogen on the a-SiGe:H Films

Microcrystalline Silicon Germanium: An Attractive Bottom-Cell Material for Thin-Film Silicon-Based Tandem-Solar-Cells

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