Disclosed are a solar cell module and a method of fabricating the same. The solar cell module includes a back electrode layer disposed on a support substrate and having a first separation pattern, a light absorbing layer disposed on the back electrode layer and having a second separation pattern, and a plurality of solar cells disposed on the light absorbing layer and formed with a front electrode layer including an insulator.

A method of making a GaN device includes: forming a GaN substrate; forming a plurality of spaced-apart first metal contacts directly on the GaN substrate; forming a layer of insulating GaN on the exposed portions of the upper surface; forming a stressor layer on the contacts and the layer of insulating GaN; forming a handle substrate on the first surface of the stressor layer; spalling the GaN substrate that is located beneath the stressor layer to separate a layer of GaN and removing the handle substrate; bonding the stressor layer to a thermally conductive substrate; forming a plurality of vertical channels through the GaN to define a plurality of device structures; removing the exposed portions of the layer of insulating GaN to electrically isolate the device structures; forming an ohmic contact layer on the second surface; and forming second metal contacts on the ohmic contact layer.

In order to improve the photoelectric conversion efficiency of a photoelectric conversion device, this photoelectric conversion device is provided with an electrode layer, a first semiconductor layer that is positioned on the electrode layer and contains a polycrystalline semiconductor, and a second semiconductor layer that is positioned on/above the first semiconductor layer and forms a p-n junction with the first semiconductor layer, and an average grain diameter of crystal grains in the first semiconductor layer is larger near the surface on the electrode layer side of the first semiconductor layer than the center of the first semiconductor layer in a thickness direction of the first semiconductor layer. Furthermore, the average grain diameter of the crystal grains in the first semiconductor layer is larger in a surface portion on the second semiconductor layer side of the first semiconductor layer than in the central portion.

A device having a plurality of thin film photovoltaic cells (PV) formed over a passivation layer. The device comprises a plurality of thin film photovoltaic (PV) cells formed over the passivation layer, each PV cell includes at least a lower conducting layer (LCL) and an upper conducting layer (UCL); and a conducting path connecting at least a UCL of a first PV cell to at least a LCL of a second PV cell, wherein at least a first array of PV cells comprised of at least a first portion of the plurality of PV cells is connected by the respective UCL and LCL of each PV cell to provide a first voltage output. In an embodiment the passivation layer is formed over a target integrated circuit (TIC), the TIC having a top surface and a bottom surface.

Back side connection layer for a photo-voltaic module with a plurality of PV-cells (1, 2). The PV-cells (1, 2) are of a type having a plurality of back side contacts (11, 12). A by-pass diode connection path (6) is formed in the back side connection layer (3) along an edge direction of two adjacent cells (1, 2) with a straight or meandering pattern around outer contacts (4, 5) of the plurality of back side contacts (11, 12) of the two adjacent cells (1, 2).

A photovoltaic structure can include two or more sets of parallel conductive fingers on a top surface and a bottom surface, such that the fingers can collect an electric current from the underlying photovoltaic structure. A scribing system can scribe a groove of a predetermined depth near and perpendicular to the plurality of fingers of the photovoltaic structure, and the photovoltaic structure can be cleaved along the groove to produce multiple strips that each can include a set of parallel fingers. An adhesive dispense system may deposit a band of conductive adhesive that can overlap a set of parallel fingers on each strip, and the strips may be overlapped over the conductive adhesive to form a string of cascaded strips. An adhesive-curing system can include an oven that may cure the conductive adhesive on one or more strips of the string at a time.

A flexible substrate material having opposed front and back sides and extending in an X-Y plane, the front side being provided with a first electrode layer and further provided with at least one thin film to form at least one thin film device stack; the thin film device stack extending from the X-Y plane in a Z direction perpendicular to the X-Y plane to a distance T; the substrate material having at least one protective structure applied to at least one of the substrate material sides, the first electrode layer and the at least one thin film; the at least one protective structure extending in the Z direction to a distance S from the X-Y plane, the distance S being greater than the distance T.

A solar cell of the present invention includes a collecting electrode on one main surface of a photoelectric conversion section. The collecting electrode includes first and second electroconductive layers in this order from the photoelectric conversion section side, and an insulating layer between the first and second electroconductive layers, the insulating layer having an opening section formed therein. The first electroconductive layer is covered with the insulating layer, contains a low-melting-point material, and is conductively connected with a part of the second electroconductive layer via the opening section. The surface roughness of the second electroconductive layer is preferably 1.0 m to 10.0 m. The second electroconductive layer is preferably formed by a plating method. In order to conductively connect the first and second electroconductive layers, annealing of the first electroconductive layer by heating is preferably performed prior to forming the second electroconductive layer.

A solar cell structure for wireless charging includes a substrate and at least one thin film solar cell disposed on a surface of the substrate, wherein the thin film solar cell has a winding coil structure. Accordingly, in the thin film solar cell, the electrode which is the winding coil structure may be used as electromagnetic induction coil or millimeter-wave radio wave receiving radiator.

A thin-film solar module with a substrate and a layer structure applied thereon that comprises a rear electrode layer, a front electrode layer, and an absorber layer arranged between the back electrode layer and the front electrode layer. Serially connected solar cells are formed in the layer structure by patterning zones, wherein each patterning zone comprises a first patterning line for subdividing at least the rear electrode layer, a second patterning line for subdividing at least the absorber layer, and at least one third patterning line for subdividing at least the front electrode layer. At least one patterning zone has one or more optically transparent zones in a zone region reduced by the first patterning line, which are in each case rear-electrode-layer-free, wherein the one or more optically transparent zones are implemented such that the rear electrode layer is continuous in the zone region.