A solar battery device includes a semiconductor substrate and a covering part. The semiconductor substrate has a first semiconductor region and a second semiconductor region. The first semiconductor region is a first-conductivity-type semiconductor region located on a first surface of the semiconductor substrate. The second semiconductor region is a second-conductivity-type semiconductor region different from the first-conductivity-type and located on a second surface opposite from the first surface. The covering part is located on the first surface of the semiconductor substrate. The covering part has a laminated portion in which a plurality of layers including a passivation layer and an antireflection layer are present in a laminated state. In the laminated portion, the passivation layer includes a region in which a thickness decreases from an outer peripheral portion toward a central part of the first surface.

Methods for producing single crystal silicon ingots in which the dopant concentration in the silicon melt is controlled are disclosed. The control of the dopant concentration enhances ingot quality by the reduction or elimination of dislocations in the neck, crown, and main body portions of the single crystal silicon ingot.

The disclosure provides a method for preparing a crystalline silicon solar cell. The method includes: (1) forming a textured surface on a front face of a silicon wafer; (2) depositing a tunneling layer and a doped polysilicon layer on the textured surface of the silicon wafer; (3) depositing a first anti-reflection film layer on the front face of the silicon wafer; and (4) removing the tunneling layer by a laser, the doped polysilicon layer, and the first anti-reflection film layer from a non-electrode region on the front face of the silicon wafer.

A method includes etching silicon using a mixture of nitric acid and hydrofluoric acid in which less than 6 mols of hydrofluoric acid is used to etch one mol of silicon. The etching may be conducted at an elevated temperature, such as a temperature of at least 70 degrees Celsius.

Method and structural embodiments are described which provide an integrated structure using polysilicon material having different optical properties in different regions of the structure.

The present application relates to the technical field of solar cells, and in particular, to a method for preparing a solar cell, the solar cell, and a photovoltaic module. The method for preparing the solar cell includes: providing a substrate; forming a doped amorphous silicon layer on the first side of the substrate; performing laser treatment N times on the doped amorphous silicon layer to form N doped polysilicon layers ranging from a first doped polysilicon layer to a Nth doped polysilicon layer stacked in a direction away from the substrate, where N>1, a power, a wavelength and a pulse irradiation number of a nth laser treatment are respectively smaller than a power, a wavelength and a pulse irradiation number of a (n−1).sub.th laser treatment, where n≤N, and the first doped polysilicon layer is disposed closer to the substrate than the Nth doped polysilicon layer. The embodiments of the present application are conducive to simplify the process of forming the solar cell.

The present invention relates to a photovoltaic device (10) comprising: a first conducting layer (16), a second conducting layer electrically insulated from the first conducting layer, a porous substrate (20) made of an insulating material arranged between the first and second conducting layers, a light absorbing layer (1) comprising a plurality of grains (2) of a doped semiconducting material disposed on the first conducting layer (16) so that the grains are in electrical and physical contact with the first conducting layer, and a charge conductor (3) made of a charge conducting material partly covering the grains and arranged to penetrate through the first conducting layer (16) and the porous substrate such that a plurality of continuous paths (22) of charge conducting material is formed from the surface of the grains (2) to the second conducting layer (18), wherein the first conducting layer (16) comprises a conducting material, an oxide layer (28) formed on the surface of conducting material, and an insulating coating (29) made of an insulating material deposited on the oxide layer (28) so that the oxide layer and the insulating coating together electrically insulate said paths (22) from the conducting material of the first conducting layer (16).

The present invention relates to a light absorbing layer (1a) for a photovoltaic device, comprising a plurality of grains (2) of a doped semiconducting material and a charge conductor (3) made of a charge conducting material in physical contact with the grains. The grains are partly covered with the charge conductor (3) so that a plurality of junctions (4) are formed between the grains and the charge conductor. The present invention also relates to a photovoltaic device comprising the light absorbing layer (1a).

Provided is a Chemical vapor deposition (CVD) equipment including a chamber having an inner space, a plurality of silicon wafers disposed in the inner space of the chamber in an upright position; and a plurality of shower nozzles configured to inject a mixed gas composed of a silicon deposition gas and an impurity gas toward each side edge of the plurality of wafers. The plurality of shower nozzles can be disposed at both sides of the plurality of the plurality of silicon wafers.

The present application relates to the technical field of solar cells, and in particular, to a method for preparing a solar cell, the solar cell, and a photovoltaic module. The method for preparing the solar cell includes: providing a substrate; forming a doped amorphous silicon layer on the first side of the substrate; performing laser treatment N times on the doped amorphous silicon layer to form N doped polysilicon layers ranging from a first doped polysilicon layer to a Nth doped polysilicon layer stacked in a direction away from the substrate, where N>1, a power, a wavelength and a pulse irradiation number of a nth laser treatment are respectively smaller than a power, a wavelength and a pulse irradiation number of a (n-1).sub.th laser treatment, where nN, and the first doped polysilicon layer is disposed closer to the substrate than the Nth doped polysilicon layer. The embodiments of the present application are conducive to simplify the process of forming the solar cell.