Thermal compression bonding 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 placing a metal foil over a metalized surface of a wafer of the solar cell. The method also includes locating the metal foil with the metalized surface of the wafer. The method also includes, subsequent to the locating, applying a force to the metal foil such that a shear force appears between the metal foil and the metallized surface of the wafer to electrically connect a substantial portion of the metal foil with the metalized surface of the wafer.

Disclosed is a solar cell. The solar cell includes a semiconductor substrate, conductivity-type regions located in or on the semiconductor substrate, electrodes conductively connected to the conductivity-type regions, and insulating films located on at least one of opposite surfaces of the semiconductor substrate, and including a first film and a second film located on the first film, the second film has a higher carbon content than that of the first film, a refractive index of the second film is equal to or less than a refractive index of the first film, and an extinction coefficient of the second film is equal to or greater than an extinction coefficient of the first film.

This disclosure relates to semiconductor devices and methods for fabricating semiconductor devices. Particularly, the disclosure relates to back-contact-only multijunction solar cells and the process flows for making such solar cells, including a wet etch process that removes semiconductor materials non-selectively without major differences in etch rates between heteroepitaxial III-V semiconductor layers.

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.

Methods of fabricating solar cell emitter regions using ion implantation, and resulting solar cells, are described. In an example, a method of fabricating alternating N-type and P-type emitter regions of a solar cell involves forming a silicon layer above a substrate. Dopant impurity atoms of a first conductivity type are implanted, through a first shadow mask, in the silicon layer to form first implanted regions and resulting in non-implanted regions of the silicon layer. Dopant impurity atoms of a second, opposite, conductivity type are implanted, through a second shadow mask, in portions of the non-implanted regions of the silicon layer to form second implanted regions and resulting in remaining non-implanted regions of the silicon layer. The remaining non-implanted regions of the silicon layer are removed with a selective etch process, while the first and second implanted regions of the silicon layer are annealed to form doped polycrystalline silicon emitter regions.

This disclosure provides back contact cell and solar cell module. The back contact cell comprises a semiconductor substrate, the semiconductor substrate is provided with a front surface and a back surface opposite to each other, the back surface includes a plurality of adjacent and alternately arranged segment units, a segment space is formed between segment unit and the backlight surface; the segment space further includes a first space, a second space, a third space and a fourth space; a first passivation layer, located only in the first space in each segment space; a first doped semiconductor layer, located only in the first space in each segment space, and being adjacent to a side of the first passivation layer away from the semiconductor substrate; a second passivation layer, located only in the second spacethe fourth space in each segment space; and a second doped semiconductor layer located only in the second spacethe fourth space in each segment space, and being adjacent to a side of the second passivation layer away from the semiconductor substrate.

The present disclosure relates to a solar cell, a sliced cell and a manufacturing method thereof, a photovoltaic module, and a photovoltaic system. The solar cell includes a substrate, a doped conductive layer, a third passivation film layer, and a second dielectric layer; the doped conductive layer and the second dielectric layer being sequentially stacked on a first surface of the substrate; the third passivation film layer being stacked on a second surface of the substrate; and the first surface and the second surface of the substrate being arranged opposite to each other; wherein the substrate further includes a plurality of first side surfaces adjacent between the first surface and the second surface; and the third passivation film layer further covers at least part of surfaces of the plurality of first side surfaces. The solar cell, the photovoltaic module, and the photovoltaic system in the present disclosure can reduce recombination losses at side edges of the solar cell and improve efficiency.

Provided are an interdigitated back contact solar cell (10,a,b,c), comprising a monocrystalline, n-doped wafer (101), a first contact area (40) which is formed by a first stack on the surface of said monocrystalline wafer (101), said first stack comprising a thin silicon oxide layer (201) and a highly n-doped polycrystalline silicon layer (301), and a second contact area (20) which is formed by a second stack on the same surface of said monocrystalline wafer (101) as said first stack, said second stack comprising a thin silicon oxide layer (202) and a highly p-doped polycrystalline silicon layer (701), wherein a p-doped monocrystalline silicon region (801) is located in a gap (30) between said first contact area (40) and said second contact area (20) and a method for producing such an interdigitated back contact solar cell (10,a,b,c).

A jettable etchant composition includes 1 to 90 wt % active ingredient, and a remainder containing any combination of the following: 10 to 90 wt % solvent, 0 to 10 wt % reducing agents, <1 to 20 wt % pickling agent, 0 to 5 wt % surfactant, and 0 to 5 wt % antifoam agent. The composition can also include a soluble compound containing at least one element which when dissolved has a higher standard electrode potential than a metal to be etched or a soluble compound containing a group IA element, and a soluble platinum group metal. An ink composition can include a group VA compound or a group IIIA compound in a solvent system formulated to be jettable on a surface at a drop volume of about 5 to about 10 picoliters and to achieve a final sheet resistance of less than about 20 / of the surface upon activation.