This invention relates to cells and devices for harvesting light. Specifically the cell comprises at least one electrode which comprises graphene or modified graphene and layer of a transition metal dichalcogenide in a vertical heterostructure. The cell may be part of a light harvesting device. The invention also relates to materials and methods for making such cells and devices.

A pixel of a complementary metal-oxide-semiconductor (CMOS) image sensor includes a semiconductor substrate having a first surface and a third surface formed by removing part of the semiconductor substrate from a second surface, an active region which is formed between the first surface and the third surface and which contains a photoelectric conversion element generating charges in response to light incident on the substrate at the third surface, and a trench-type isolation region formed from either of the first and third surfaces to isolate the active region from an adjacent active region. The trench-type isolation region is filled with first material in a process that leaves a void in the material, the void is filled or partially filled with second material, and then a layer of third material is formed over the resulting structure composed of the first and second materials.

A stacked-layered thin film solar cell. The solar cell has reduced absorber thickness and an improved back contact for Copper Indium Gallium Selenide solar cells. The back contact provides improved reflectance particularly for infrared wavelengths while still maintaining ohmic contact to the semiconductor absorber. This reflectance is achieved by producing a back contact having a highly reflecting metal separated from an absorbing layer with a dielectric layer.

Disclosed herein are a solar cell and a method of manufacturing the same. The solar cell module includes a semiconductor substrate, a first passivation film located on a front surface of the semiconductor substrate, a second passivation film located on a rear surface of the semiconductor substrate, a front electric field region located on the first passivation film on the front surface of the semiconductor substrate and being of a same conductivity-type as that of the semiconductor substrate, an emitter region located on the second passivation film on the rear surface of the semiconductor substrate and being of a conductivity-type opposite that of the semiconductor substrate, first electrodes conductively connected to the front electric field region, and second electrode conductively connected to the emitter region.

Methods for depositing a metal film comprising forming an amorphous silicon layer as a nucleation layer and/or glue layer on a substrate. Some embodiments further comprise the incorporation of a glue layer to increase the ability of the amorphous silicon layer and metal layer to stick to the substrate.

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.

Laser foil trim approaches for foil-based metallization of solar cells, and the resulting solar cells, are described. For example, a method of fabricating a solar cell includes attaching a metal foil sheet to a surface of a wafer to provide a unified pairing of the metal foil sheet and the wafer, wherein the wafer has a perimeter and the metal foil sheet has a portion overhanging the perimeter. The method also includes laser scribing the metal foil sheet along the perimeter of the wafer using a laser beam that overlaps the metal foil sheet outside of the perimeter of the wafer and at the same time overlaps a portion of the unified pairing of the metal foil sheet and the wafer inside the perimeter of the wafer to remove the portion of the metal foil sheet overhanging the perimeter and to provide a metal foil piece coupled to the surface of the wafer.

Aspects relate to a system and a method of manufacturing an integrated device. The method includes providing a circuit board, configuring an upper surface of the circuit board as a substrate, integrally depositing photovoltaic device layers that include at least a semi-conductor absorber layer, a buffer layer, and a top electrode layer on the upper surface of the circuit board to form a photovoltaic device using the upper surface of the circuit board as a photovoltaic device substrate, wherein the buffer layer is integrally deposited between the semi-conductor absorber layer and the top electrode, and electrically connecting the photovoltaic device to one or more on-board electronic components.

Aspects relate to a system and a method of operating an integrated device is provided. The method includes providing a circuit board that includes one or more on-board electronic components and an upper surface configured as a substrate, providing photovoltaic device layers that include at least a semi-conductor absorber layer, a buffer layer, and a top electrode layer on the upper surface of the circuit board that form a photovoltaic device using the upper surface of the circuit board as a photovoltaic device substrate, wherein the buffer layer is integrally deposited between the semi-conductor absorber layer and the top electrode, generating electricity using the photovoltaic device, and powering one or more of the on-board electronic components using the electricity from the photovoltaic device.

In one example, a device includes a trench formed in a substrate. The trench includes a first end and a second end that are non-collinear. A first plurality of semiconductor pillars is positioned near the first end of the trench and includes integrated light sources. A second plurality of semiconductor pillars is positioned near the second end of the trench and includes integrated photodetectors.