A method for preparing TOPCon battery substrate and double-sided electroplated TOPcon battery prepared therefrom are provided. The method includes: providing a double-sided grooved silicon matrix of a TOPCon battery; carrying out thermal repair treatment on the silicon matrix; respectively carrying out light injection treatment on the front side and the back side of the silicon matrix after thermal repair treatment, thereby the TOPCon battery substrate is obtained. Thermal repair treatment can greatly increase the overall lattice thermal motion of the silicon substrate, and light is injected into the front side and the back side in the directions of two different light incidence surfaces, so that both the front side and the back side can absorb light, thereby repairing the defects at the interface between the amorphous silicon and the silicon wafer and improving the quality of the PN junctions.

A modified tunnel oxide layer and a preparation method, a TOPCon structure and a preparation method, and a solar cell are provided. The modified tunnel oxide layer is SiO.sub.x subjected to plasma surface treatment, and a Si.sup.4+ content in the SiO.sub.x is greater than or equal to above 18%. The density of the interface state subjected to plasma surface treatment decreases, and compared with the silicon oxide layer prepared in the prior arts, boron has a low diffusion rate in the modified silicon oxide layer and hence the damaging effect of the boron on the tunnel oxide layer is reduced effectively, thereby improving the integrity of the silicon oxide layer and maintaining chemical passivation effect. The modified tunnel oxide layer significantly increases the performance indexes of the TOPCon structure.

A solar cell comprising a semiconductor substrate, first semiconductor layers, second semiconductor layers, a band-like first base electrode stacked on the first semiconductor layer, a band-like second base electrode stacked on the second semiconductor layer, a first electrode insulation stacked on the first base electrodes, a second electrode insulation stacked on the second base electrodes, an intermediate insulation stacked on a region of the first semiconductor layer in which the first base electrode is not stacked, and a region of the second semiconductor layer in which the second base electrode is not stacked, a first current collector stacked to span the second electrode insulation and the intermediate insulation, and a second current collector stacked to span the first electrode insulation and the intermediate insulation.

Provided are a back-contact battery and a manufacturing method thereof, and a photovoltaic module, which includes a silicon substrate with a front surface and a back surface; a first semiconductor layer with a second semiconductor opening region arranged back surface; and a second semiconductor layer. The back-contact battery further includes multiple insulating layers arranged at intervals along an X-axis direction of the back surface, wherein the insulating layers are arranged on the outer surface of the second semiconductor layer. In the X-axis direction, the insulating layer spans a side-surface edge of the second semiconductor opening region with both ends extending, respectively; the insulating layer has a span length W12 on the second semiconductor opening region, and the insulating layer has a span length W11 on the first semiconductor layer, satisfying a condition: W12:W11=0.1-10:1.

A method of treatment of at least one cut solar cell, the method including steps of: providing the at least one solar cell, said cell having previously been subjected to a cutting process; and performing a carrier injection treatment on at least a cut edge of the cell.

A heterojunction solar cell includes a cell substrate and a conductive layer. The conductive layer includes a first transparent conductive film, a silver electrode, and a second transparent conductive film. The first transparent conductive film is disposed on a surface of the cell substrate, the silver electrode is disposed on a partial region of the first transparent conductive film, and the second transparent conductive film covers the silver electrode and the first transparent conductive film.

In one aspect, a solar cell includes: a monocrystalline silicon substrate; an intrinsic amorphous silicon layer disposed on the monocrystalline silicon substrate; a doped amorphous silicon layer disposed on the intrinsic amorphous silicon layer; a transparent conductive film layer disposed on the doped amorphous silicon layer; and an electrode disposed on the transparent conductive film layer and in direct contact with the doped amorphous silicon layer.

The present disclosure relates to large cell sheets, solar cells, shingled solar modules, and manufacturing method thereof. A top surface of a boundary portion of units of the large cell sheet is divided into a cutting area, top surface bonding areas and top surface electrically-conductive contact areas. The cutting area is configured in a way that the large cell sheet can be cut along the cutting area; the top surface bonding areas and the top surface electrically-conductive contact areas are provided alternately, the cutting area and the top surface electrically-conductive contact areas are formed as an overlapping edge of the solar cell, and after the splitting of the large cell sheet, the top surface electrically-conductive contact areas can directly contact the bottom surface of another solar cell to achieve electrically-conductive connection. The large cell sheet according to the present disclosure can be split conveniently, and the individual solar cells are provided with dedicated bonding areas and electrically-conductive contact areas. Such an arrangement can optimize the production process and use performance of the solar cells.

The present application discloses a zinc oxide-crystalline silicon laminated solar cell and a preparation method thereof, relates to the technical field of solar cells, and aims to solve the technical problem of low photoelectric conversion rate of existing solar cells. The zinc oxide-crystalline silicon laminated solar cell includes: a P-type silicon substrate layer; a front surface of the P-type silicon substrate layer being sequentially formed with, from bottom to top, a diffusion layer, an N-type zinc oxide layer, a first passivation layer, and a first antireflection layer; wherein the N-type zinc oxide layer is made of tetrapod-like N-type zinc oxide whisker powder as a raw material; and a back surface of the P-type silicon substrate layer being sequentially formed with, from top to bottom, a second passivation layer and a second antireflection layer; and an electrode, the electrode including a front electrode and a back electrode.

The present application discloses a zinc oxide-crystalline silicon laminated solar cell and a preparation method thereof, relates to the technical field of solar cells, and aims to solve the technical problem of low photoelectric conversion rate of existing solar cells. The zinc oxide-crystalline silicon laminated solar cell includes: a P-type silicon substrate layer; a front surface of the P-type silicon substrate layer being sequentially formed with, from bottom to top, a diffusion layer, an N-type zinc oxide layer, a first passivation layer, and a first antireflection layer; wherein the N-type zinc oxide layer is made of tetrapod-like N-type zinc oxide whisker powder as a raw material; and a back surface of the P-type silicon substrate layer being sequentially formed with, from top to bottom, a second passivation layer and a second antireflection layer; and an electrode, the electrode including a front electrode and a back electrode.