An optoelectronic device has a hybrid metal-dielectric optoelectronic interface including an array of nanoscale dielectric resonant elements (e.g., nanopillars), and a metal film disposed between the dielectric resonant elements and below a top surface of the resonant elements such that the dielectric resonant elements protrude through the metal film. The device may also include an anti-reflection coating. The device may further include a metal film layer on each of the dielectric resonant elements.

A solar cell and a photovoltaic module including the same are provided. The solar cell includes a substrate having a first surface and a second surface opposite to each other; a first passivation stack disposed on the first surface and including a first oxygen-rich dielectric layer, a first silicon-rich dielectric layer, a second oxygen-rich dielectric layer, and a second silicon-rich dielectric layer that are sequentially disposed in a direction away from the first surface, wherein an atomic fraction of oxygen in the first oxygen-rich dielectric layer is less than an atomic fraction of oxygen in the second oxygen-rich dielectric layer; a tunneling oxide layer disposed on the second surface; a doped conductive layer disposed on a surface of the tunneling oxide layer; and a second passivation layer disposed on a surface of the doped conductive layer.

A solar cell (10) for an electronic device, includes a substrate (100) made of a transparent material to be exposed to incident light radiation, a first electrode (110) made of a transparent, electrically conducting material, formed on one face of the substrate (100) an absorbent layer (130) extending, via an outer face (131), onto an inner face (111) of the first electrode (110), and a second electrode (120) made of an electrically conducting material and extending onto an inner face (132) of the absorbent layer (130) opposite an outer face (131) thereof, the absorbent layer (130) and the second electrode (120) being perforated so as to delimit a plurality of blind cavities (140), the bottom of each of which is formed by the inner face (111) of the first electrode (110.

The present disclosure discloses a solar cell and a manufacturing method therefor. An example method includes providing a semiconductor substrate having a first region and a second region, forming a tunneling passivation layer on at least the first region, and perform wet chemical processing on the first region and the second region to form a first surface structure in the first region and a second surface structure in the second region. An etching rate of etching the first region that is covered by the tunneling passivation layer is different from an etching rate of etching the second region. The first surface structure is different from the second surface structure.

The present disclosure provides a hybrid heterojunction solar cell, a cell component, and a preparation method, the hybrid heterojunction solar cell comprises a semiconductor substrate having a substrate front surface and a substrate back surface opposite to each other, wherein the substrate front surface is close to a light-facing side of the cell and the substrate back surface is close to a backlight side of the cell; at least two composite layers located on one side of the substrate front surface, each composite layer includes a multi-layer structure of a tunneling layer and a doped polysilicon layer sequentially arranged in a direction gradually away from the substrate front surface. The hybrid heterojunction solar cell, cell component and a preparation method provided by this disclosure can achieve a stable passivation effect on the cell surface, reduce light absorption in the non-metallic areas of the cell, and achieve better process control at the same time.

A faade element having a transparent cover plate and an opaque back element mounted on the cover plate. The cover plate has an outer surface facing the external environment and an inner surface facing the back element. The outer surface has a patterned region on which an interference layer is arranged. Alternatively, the interference layer is arranged on the inner surface. The inner surface and/or the outer surface have a patterned region having a height profile with hills and valleys. A portion of the patterned region is composed of flat segments that are inclined relative to the plane of the cover plate.

A solar cell, a method for producing a solar cell and a solar cell module are provided. The solar cell includes: a substrate having a front surface and a rear surface opposite to the front surface; a first passivation layer, a second passivation layer and a third passivation layer sequentially formed on the front surface and in a direction away from the front surface; wherein the first passivation layer includes a dielectric material; the second passivation layer includes a first silicon nitride Si.sub.mN.sub.n material, and a ratio of n/m is 0.51; the third passivation layer includes a silicon oxynitride SiO.sub.iN.sub.j material, and a ratio of j/i is 0.10.6; and a tunneling oxide layer and a doped conductive layer sequentially formed on the rear surface and in a direction away from the rear surface, wherein the doped conductive layer and the substrate have a doping element of a same conductivity type.

A solar cell includes: a substrate having a front surface and a opposite rear surface; a first dielectric layer formed over the rear surface; a first doped conductive layer formed over a surface of the first dielectric layer away from the substrate; grooves arranged alternatingly in a first direction, penetrating the first doped conductive layer and the first dielectric layer, and extending into inside of the substrate; a second dielectric layer formed over a bottom surface of the grooves; a second doped conductive layer formed over a surface of the second dielectric layer away from the substrate; and a doped layer aligned with the second doped conductive layer and located between the second dielectric layer and the substrate. The first doped conductive layer and the doped layer are doped with a first dopant element, and the substrate and the second doped conductive layer are doped with a second dopant element.

This disclosure provides a back contact solar cell and a method for manufacturing a back contact solar cell. In one example, a back contact solar cell includes a silicon substrate having first regions and second regions alternately distributed on a back surface of the silicon substrate, and a first doped semiconductor layer formed on a first region on the back surface of the silicon substrate. A groove structure concaving inward the silicon substrate relative to a surface of the first region is formed on a second region. An end portion of the first doped semiconductor layer adjacent to the second region is arranged in a suspended manner.

A solar cell, a method for manufacturing the same, and a photovoltaic module are provided. The solar cell includes a substrate, first and second doped parts, and first electrodes. The substrate has a first surface including first regions and second regions arranged alternatingly in a first direction. Each of the first and second doped parts is located on a corresponding first and second region, respectively and is separated from each other. Each first electrode and a third doped part are located on the corresponding first doped part. On the first doped part, the third doped part is located on at least one side of the first electrode in the first direction and is separated from the adjacent first electrode. The first doped parts are doped with dope elements different from the second doped parts and the third doped parts.