A method for fabricating a photovoltaic device includes forming a polycrystalline absorber layer including CuZnSnS(Se) (CZTSSe) over a substrate. The absorber layer is rapid thermal annealed in a sealed chamber having elemental sulfur within the chamber. A sulfur content profile is graded in the absorber layer in accordance with a size of the elemental sulfur and an anneal temperature to provide a graduated bandgap profile for the absorber layer. Additional layers are formed on the absorber layer to complete the photovoltaic device.

A photovoltaic device including a single junction solar cell provided by an absorption layer of a type IV semiconductor material having a first conductivity, and an emitter layer of a type III-V semiconductor material having a second conductivity, wherein the type III-V semiconductor material has a thickness that is no greater than 50 nm.

The invention relates to a method for producing a photovoltaic solar cell having at least one hetero-junction, including the following steps: A) providing a semiconductor substrate having base doping; B) producing a hetero-junction on at least one side of the semiconductor substrate, which hetero-junction has a doped hetero-junction layer and a dielectric tunnel layer arranged indirectly or directly between the hetero-junction layer and the semiconductor substrate; C) heating at least the hetero-junction layer in order to improve the electrical quality of the heterojunction. The invention is characterized in that, in a step D after step C, hydrogen is diffused into the hetero-junction layer and/or to the interface between the tunnel layer and the semiconductor substrate.

A solar cell includes a photoelectric conversion section that, includes an n-type crystal silicon substrate, a p-type silicon-based thin-film provided on a first principal surface, and an n-type silicon-based thin-film provided on a second principal surface, and further includes a first electrode layer on the p-type silicon-based thin-film, and a second electrode layer on the n-type silicon-based thin film. A patterned collector electrode is provided on the first electrode layer. On the first principal surface of the photoelectric conversion section, a wraparound portion of the second electrode layer, an insulating region where neither the first electrode layer nor the second electrode layer is provided, and a first electrode layer-formed region are arranged in this order from a peripheral end.

A solar cell is disclosed. The solar cell includes a crystalline semiconductor substrate containing impurities of a first conductivity type, a front doped layer located on a front surface of the semiconductor substrate, a back doped layer located on a back surface of the semiconductor substrate, a front transparent conductive layer located on the front doped layer and having a first thickness, a front collector electrode located on the front transparent conductive layer, a back transparent conductive layer located under the back doped layer and having a second thickness, and a back collector electrode located under the back transparent conductive layer. The first thickness of the front transparent conductive layer and the second thickness of the back transparent conductive layer are different from each other, and a sheet resistance of the front transparent conductive layer is less than a sheet resistance of the back transparent conductive layer.

A method for the production of a transparent conductor deposit on a substrate, the method comprising: providing a substrate formed from a first material; depositing a film of a second material on the substrate; causing the film to crack so as to provide a plurality of recesses; depositing a conductive material in the recesses; and removing the film from the substrate so as to yield a transparent conductive deposit on the substrate.

Discussed is a solar cell including a single crystalline semiconductor substrate having a first transparent conductive oxide layer positioned on a non-single crystalline emitter layer; a second transparent conductive oxide layer positioned over a rear surface of the single crystalline semiconductor substrate; a first electrode part including a first seed layer directly positioned on the first transparent conductive oxide layer; and a second electrode part including a second seed layer directly positioned on the second transparent conductive oxide layer, wherein the first transparent conductive oxide layer and the first seed layer have different conductivities, and wherein the second transparent conductive oxide layer and the second seed layer have different conductivities.

A solar cell is provided with an electrode layer on a photovoltaic conversion section including a crystalline silicon substrate. Deposition of the electrode layer is performed by a deposit-up method with a substrate being mounted in such a manner that an opening edge portion of a mask plate having an opening is in contact with the substrate. The opening edge portion of the mask plate has a tapered surface at a part that is in contact with first principal surface of the substrate, the tapered surface conforming to a deflection angle at a peripheral end of the substrate. A solar cell having a large effective area can be prepared by suppressing deposition of electrode layer on mask-covered region due to penetration.

Electrically conductive, thin, smooth films are provided that comprise silver (Ag) and a conductive metal, such as aluminum (Al), titanium (Ti), nickel (Ni), chromium (Cr), gold (Au), magnesium (Mg), tantalum (Ta), germanium (Ge) or combinations thereof. In other alternative variations, electrically conductive, thin, smooth films are provided that comprise gold (Au) or copper (Cu) and a conductive metal, such as aluminum (Al), titanium (Ti), nickel (Ni), chromium (Cr), gold (Au), magnesium (Mg), tantalum (Ta), germanium (Ge) or combinations thereof. Such materials have excellent electrical conductivity, may be ultra-thin, flexible, transparent, and have low optical loss. Assemblies incorporating such films and methods of making the films are also provided. The assemblies may be used in photovoltaic and light emitting devices with high power conversion efficiencies or optical meta-materials that exhibit high transmittance and homogeneous response, among others.

A sample-holding device for holding and lifting a sample includes a sample-holding surface facing the sample; and a positioning member provided at a peripheral part of the sample-holding surface, the positioning member comprising a contact part having an outward-facing part on a back side thereof; a first rounded or chamfered end; and a second rounded or chamfered end, wherein the contact part contacts with part of the sample when the sample is held or when the sample is off-point, wherein the first end is an end of a section comprising the contact part or a part smoothly continuing from the contact part, the end being on a distant side from the sample-holding surface, and the second end is an end of the outward-facing part, the end being located on a tipping side of the outward-facing part.