METHOD FOR FORMING A SOLAR CELL WITH A SELECTIVE EMITTER
First Claim
1. A method for producing a solar cell, comprising the steps of:
- a) providing a semiconductor substrate doped with a base dopant type;
b) forming a layer of dopant source material of an emitter dopant type opposite to the base dopant type at a surface of the semiconductor substrate;
c) applying heat to the layer of dopant source material to thereby diffuse dopants from the layer of dopant source material into an adjacent surface area of the semiconductor substrate for forming a homogeneous lightly doped emitter region;
d) in a first lasering step, locally applying laser light to contact surface areas of the semiconductor substrate surface to thereby additionally generate electrically active dopants in the contact surface areas of the semiconductor substrate for forming a selective heavily doped emitter region;
e) in a second lasering step, locally applying laser light to the contact areas of the semiconductor substrate surface to thereby locally remove at least one of the layer of dopant source material and a dielectric layer formed at the surface of the semiconductor substrate to thereby locally expose the surface of the semiconductor substrate in the contact surface areas,wherein in the second lasering step other laser characteristics apply than in the first lasering step;
f) forming metal contacts which electrically contact the surface of the semiconductor substrate in the locally exposed contact surface areas.
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Accused Products
Abstract
A method for producing a solar cell with a selective emitter is disclosed. A semiconductor substrate (1) is provided. A layer (3) of dopant source material with a dopant type opposite to the dopant type of the substrate (1) is formed at a surface of the substrate (1). By applying heat to the layer (3), a homogeneous lightly doped emitter region (5) is formed. In a first lasering step, selective heavily doped emitter regions (11) are formed by applying laser light (7) to contact surface areas (9). Optionally, the layer (3) is subsequently removed and an additional dielectric layer (15) is applied to the front side of the substrate (1). In a second lasering step, the layer (3) or the layer (15) are locally removed by applying laser light (21) to the contact surface areas (9), thereby locally exposing the surface of the substrate (1). In the locally exposed contact surface areas (9), metal contacts (23) are finally formed, using for example metal-plating techniques. Using two different lasering steps for laser doping, on the one hand, and laser removal for forming the metallization mask, on the other hand, allows optimizing each of the lasering steps independently from each other, thereby enabling improvements for the processing and resulting solar cell.
13 Citations
10 Claims
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1. A method for producing a solar cell, comprising the steps of:
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a) providing a semiconductor substrate doped with a base dopant type; b) forming a layer of dopant source material of an emitter dopant type opposite to the base dopant type at a surface of the semiconductor substrate; c) applying heat to the layer of dopant source material to thereby diffuse dopants from the layer of dopant source material into an adjacent surface area of the semiconductor substrate for forming a homogeneous lightly doped emitter region; d) in a first lasering step, locally applying laser light to contact surface areas of the semiconductor substrate surface to thereby additionally generate electrically active dopants in the contact surface areas of the semiconductor substrate for forming a selective heavily doped emitter region; e) in a second lasering step, locally applying laser light to the contact areas of the semiconductor substrate surface to thereby locally remove at least one of the layer of dopant source material and a dielectric layer formed at the surface of the semiconductor substrate to thereby locally expose the surface of the semiconductor substrate in the contact surface areas, wherein in the second lasering step other laser characteristics apply than in the first lasering step; f) forming metal contacts which electrically contact the surface of the semiconductor substrate in the locally exposed contact surface areas. - View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 9, 10)
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Specification