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.

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 photovoltaic device is provided that includes a semiconductor substrate including a p-n junction with a p-type semiconductor portion and an n-type semiconductor portion one lying on top of the other, wherein an upper exposed surface of the semiconductor substrate represents a front side surface of the semiconductor substrate. A plurality of patterned antireflective coatings is located on the front side surface to provide a grid pattern including a busbar region and finger regions. The busbar region includes at least a real line interposed between at least two dummy lines. A material stack including at least one metal layer located on the semiconductor substrate in the busbar region and the finger regions.

The invention relates to a passivated emitter rear solar cell, comprising a silicon substrate having a front and back surface, a rear passivation layer on the back surface of the silicon substrate having a plurality of open holes formed therein, an aluminum back contact layer formed in the open holes of the rear passivation layer, and at least one backside soldering tab on the back surface of the silicon substrate. The backside soldering tab is formed from an electroconductive paste composition comprising conductive metallic particles, at least one lead-free glass frit, and an organic vehicle comprising at least one silicone oil.

A method of forming an electrode, an electrode for a solar cell manufactured, and a solar cell, the method including forming a pattern of a finger electrode by: coating a composition for forming a first electrode that includes a conductive powder, an organic vehicle, and a first glass frit that is free of silver and phosphorus, and drying the coated composition for forming a first electrode; forming a pattern of a bus electrode by: coating a composition for forming a second electrode that includes a conductive powder, an organic vehicle, and a second glass fit that includes silver and phosphorus, and drying the coated composition for forming a second electrode; and firing the resultant patterns.

Disclosed are a photovoltaic with improved visibility, which can improve optical-to-electric conversion efficiency and can be applied to a window of a building or a view window of a moving means such as a vehicle, and a method of manufacturing the same. The photovoltaic includes a transparent substrate, a transparent electrode formed on one surface of the transparent substrate, a plurality of photovoltaic cells configured to each include a first electrode formed on the transparent electrode, an optical-to-electric conversion part formed on the first electrode, and a second electrode formed on the optical-to-electric conversion part, and a separation part provided between adjacent photovoltaic cells. The separation part exposes the transparent electrode to incident sunlight.

A self-powered electronic system comprises a first chip (401) of single-crystalline semiconductor embedded in a second chip (302) of single-crystalline semiconductor shaped as a container bordered by ridges. The assembled chips are nested and form an electronic device assembled, in turn, in a slab of weakly p-doped low-grade silicon shaped as a container (330) bordered by ridges (331). The flat side (335) of the slab includes a heavily n-doped region (314) forming a pn-junction (315) with the p-type bulk. A metal-filled deep silicon via (350) through the p-type ridge (331) connects the n-region with the terminal (322) on the ridge surface as cathode of the photovoltaic cell with the p-region as anode. The voltage across the pn-junction serves as power source of the device.

An optoelectronic device including at least one of a solar device, a semiconductor device, and an electronic device. The device includes a semiconductor unit. A plurality of metal fingers is disposed on a surface of the semiconductor unit for electrical conduction. Each of the metal fingers corresponds to a section of the optoelectronic device. A plurality of pad areas is available for connection to a bus bar, wherein each of the metal fingers is connected to a corresponding pad area for forming an electrical contact. The optoelectronic device includes a bad section, wherein the bad section is associated with a compromised metal finger and a compromised pad area. A dielectric spot coating is disposed above the compromised pad area to electrically isolate the bad section.

There is provided a metal-based particle assembly comprising 30 or more metal-based particles separated from each other and disposed in two dimensions, the metal-based particles having an average particle diameter in a range of from 200 to 1600 nm, an average height in a range of from 55 to 500 nm, and an aspect ratio, as defined by a ratio of the average particle diameter to the average height, in a range of from 1 to 8, wherein the metal-based particle assembly has in an absorption spectrum for a visible light region a maximum wavelength of a peak at a longest side in wavelength, and an absorbance at the maximum wavelength is higher as compared with that of a reference metal-based particle assembly, on the premise that the numbers of the metal-based particles are the same. The metal-based particle assembly of the present invention presents significantly intense plasmon resonance.

The invention relates to a method for obtaining a magnesium fluoride (MgF.sub.2) sol solution, comprising the steps of providing a magnesium alkoxide precursor in a non-aqueous solvent and adding 1.85 to 2.05 molar equivalents of non-aqueous hydrofluoric acid to said magnesium precursor, characterized in that the reaction proceeds in the presence of carbon dioxide. The invention further relates to sol solutions, method of applying the sol solutions of the invention to surfaces as a coating, and to antireflective coatings obtained thereby.