A composition of matter, in particular a photovoltaic cell, comprising: at least one core semiconductor nanowire on a graphitic substrate, said at least one core nanowire having been grown epitaxially on said substrate wherein said nanowire comprises at least one group III-V compound or at least one group II-VI compound or at least one group IV element; a semiconductor shell surrounding said core nanowire, said shell comprising at least one group III-V compound or at least one group II-VI compound or at least one group IV element such that said core nanowire and said shell form a n-type semiconductor and a p-type semiconductor respectively or vice versa; and an outer conducting coating surrounding said shell which forms an electrode contact.

The present invention relates to a solar cell comprising a heterojunction photoelectric device comprising, a front electrode layer, a back electrode layer comprising a metallic contact layer, a light-absorbing silicon layer arranged between said front electrode and said back electrode layers and a doped silicon-based layer arranged between said light-absorbing silicon layer and said back electrode layer, characterized in that said heterojunction photoelectric device further comprises a wide band gap material layer having an electronic band gap greater than 1.4 eV, said wide band gap material layer being applied on a surface of the light-absorbing silicon layer between said light-absorbing silicon layer and said doped silicon-based layer. The present heterojunction layer or stack of layers is compatible with thermal annealing and firing processes at T above 600° C.

In a method of manufacturing a solar cell, a groove is formed on a first surface of an n-type semiconductor substrate. A p-side transparent conductive film layer is formed on the first surface of the n-type semiconductor substrate formed with the groove. A non-deposition area, where the p-side transparent conductive film layer is not formed, is formed in at least a part of a side surface of the groove formed on the first surface of the n-type semiconductor substrate.

A light detection device includes a substrate, a buffer layer disposed on the substrate, a first band gap change layer disposed on a portion of the buffer layer, a light absorption layer disposed on the first band gap change layer, a Schottky layer disposed on a portion of the light absorption layer, and a first electrode layer disposed on a portion of the Schottky layer.

A photovoltaic device is presented. The photovoltaic device includes a buffer layer disposed on a transparent conductive oxide layer; a window layer disposed on the buffer layer; and an interlayer interposed between the transparent conductive oxide layer and the window layer. The interlayer includes a metal species, wherein the metal species includes gadolinium, beryllium, calcium, barium, strontium, scandium, yttrium, hafnium, cerium, lutetium, lanthanum, or combinations thereof. A method of making a photovoltaic device is also presented

A method for producing a rear-side contact system for a silicon thin-film solar cell having pn junction formed from a silicon absorber layer and an emitter layer includes applying an organic insulation layer to the emitter layer; producing contact holes in the insulation layer as far as the absorber layer and the emitter layer; subsequently insulating the contact holes; subsequently applying a low-melting metal layer to form n and p contacts in the contact holes; separating the metal layer into n-contacting and p-contacting regions by laser-cutting; before applying the organic insulation layer to the emitter layer, applying a TCO layer; producing holes for contacts for the silicon absorber layer in the organic insulation; and subsequently selectively doping the produced holes for the contacts as far as the silicon absorber layer.

The invention relates to a multi-junction device comprising a) a first photoactive region comprising a layer of a first photoactive material, b) a second photoactive region comprising a layer of a second photoactive material, and c) a charge recombination layer disposed between the first and second photoactive regions, wherein the charge recombination layer comprises a charge recombination layer material, wherein one of the first and second photoactive materials comprises at least one A/M/X material; wherein the other of the first and second photoactive materials comprises at least one A/M/X material or a compound which is a photoactive semiconductor other than an A/M/X material; wherein each A/M/X material is a crystalline compound of formula (I) [A].sub.a[M].sub.b[X].sub.c wherein: [A] comprises one or more A cations; [M] comprises one or more M cations which are metal or metalloid cations; [X] comprises one or more X anions; a is a number from 1 to 6; b is a number from 1 to 6; and c is a number from 1 to 18; and wherein the charge recombination layer material has a refractive index, η(λ), at a wavelength, λ, of at least 2, wherein λ is a wavelength of from 500 nm to 1200 nm.

The present application relates to a conductive film, a method for manufacturing the same, and a display device including the same.

Provided is a power generation battery capable of improving power generation efficiency. The power generation battery includes a first layer, a second layer, and a filter layer. The first layer includes a semiconductor element that has a main absorption region in a visible light region and absorbs a light to generate electric power. The second layer, disposed on a side opposite to an incident direction side of the first layer, includes a semiconductor element that has a main absorption region in an infrared light region and absorbs light to generate electric power. The filter layer is disposed between the first layer and the second layer and blocks or absorbs a light in the visible light region.

A solar cell includes a photoelectric conversion section having first and second principal surfaces, and a collecting electrode formed on the first principal surface. The collecting electrode includes first and second electroconductive layers in this order from the photoelectric conversion section side, and includes an insulating layer between the first and second electroconductive layers. The insulating layer is provided with an opening, and the first and second electroconductive layers are in conduction with each other via the opening provided in the insulating layer. The solar cell has, on the first principal surface, the second principal surface or a side surface of the photoelectric conversion section, an insulating region freed of a short circuit of front and back sides of the photoelectric conversion section, and the surface of the insulating region is at least partially covered with the insulating layer.