Disclosed is a method of facilitating straining of a semiconductor element (331) for semiconductor fabrication. In a described embodiment, the method comprises: providing a base layer (320) with the semiconductor element (331) arranged on a first base portion (321) of the base layer (320), the semiconductor element (331) being subjected to a strain relating to a characteristic of the first base portion (321); and adjusting the characteristic of the first base portion (321) to facilitate straining of the semiconductor element (331).

An optical sensor includes a graphene layer, a first electrode and a second electrode that are connected to the graphene layer, and an enhancement layer. The enhancement layer is disposed below the graphene layer to enhance the intensity of an optical electric field by surface plasmon resonance. The first electrode and the second electrode are arranged parallel to a first direction. The intensity of the optical electric field enhanced by the enhancement layer is greater on a first electrode side than on a second electrode side with respect to a centerline in the first direction of the graphene layer.

An optical sensor includes a graphene layer, a first electrode and a second electrode that are connected to the graphene layer, and an enhancement layer. The enhancement layer is disposed below the graphene layer to enhance the intensity of an optical electric field by surface plasmon resonance. The first electrode and the second electrode are arranged parallel to a first direction. The intensity of the optical electric field enhanced by the enhancement layer is greater on a first electrode side than on a second electrode side with respect to a centerline in the first direction of the graphene layer.

The present disclosure relates to a photodiode comprising a first part made of silicon and a second part made of doped germanium lying on and in contact with the first part, the first part comprising a stack of a first area and of a second area forming a p-n junction and the doping level of the germanium increasing as the distance from the p-n junction increases.

The present disclosure relates to a photodiode comprising a first part made of silicon and a second part made of doped germanium lying on and in contact with the first part, the first part comprising a stack of a first area and of a second area forming a p-n junction and the doping level of the germanium increasing as the distance from the p-n junction increases.

Provided is a photoelectric detector, comprising: a silicon layer (110), the silicon layer (110) comprising a first-doping-type doped region (111); a germanium layer (120) in contact with the silicon layer (110), the germanium layer (120) comprising a second-doping-type doped region (121); and a silicon nitride waveguide (130), the silicon nitride waveguide (130) being arranged surrounding the germanium layer (120) along the extension directions of at least three side walls of the germanium layer (120), wherein the silicon nitride waveguide (130) is used for transmitting an optical signal and coupling the optical signal to the germanium layer (120), and the germanium layer (120) is used for detecting the optical signal and converting the optical signal into an electrical signal.

A high efficiency configuration for a string of solar cells comprises series-connected solar cells arranged in an overlapping shingle pattern. Front and back surface metallization patterns may provide further increases in efficiency.

A high efficiency configuration for a string of solar cells comprises series-connected solar cells arranged in an overlapping shingle pattern. Front and back surface metallization patterns may provide further increases in efficiency.

A method of generating a germanium structure includes performing an epitaxial depositing process on an assembly of a silicon substrate and an oxide layer, wherein one or more trenches in the oxide layer expose surface portions of the silicon substrate. The epitaxial depositing process includes depositing germanium onto the assembly during a first phase, performing an etch process during a second phase following the first phase in order to remove germanium from the oxide layer, and repeating the first and second phases. A germanium crystal is grown in the trench or trenches. An optical device includes a light-incidence surface formed by a raw textured surface of a germanium structure obtained by an epitaxial depositing process without processing the surface of the germanium structure after the epitaxial process.

A method of generating a germanium structure includes performing an epitaxial depositing process on an assembly of a silicon substrate and an oxide layer, wherein one or more trenches in the oxide layer expose surface portions of the silicon substrate. The epitaxial depositing process includes depositing germanium onto the assembly during a first phase, performing an etch process during a second phase following the first phase in order to remove germanium from the oxide layer, and repeating the first and second phases. A germanium crystal is grown in the trench or trenches. An optical device includes a light-incidence surface formed by a raw textured surface of a germanium structure obtained by an epitaxial depositing process without processing the surface of the germanium structure after the epitaxial process.