WO2011060764A2 - Emitter formation by means of a laser - Google Patents

Abstract

The invention relates to a back-contact solar cell (4) and to a method for producing a back-contact solar cell (4), wherein in an additional process step a transparent substrate is brought in contact with the back face side of a silicon wafer, a doping material is introduced locally by means of irradiating using a laser, and then the base of the n-type silicon is contacted with the aid of a film coated with metal and a further laser process.

Description

 Emitter formation with a laser

State of the art

The invention relates to a back contact solar cell with an emitter region according to the preamble of claim 1 and to a method for emitter formation with a laser, in particular for producing a back contact solar cell, according to the preamble of claim 6.

Conventional solar cells have a front-side contact, that is, a contact disposed on a light-facing surface of the solar cell, and a back-side contact on a surface of the solar cell facing away from the light. In conventional solar cells, the largest volume fraction of a light-absorbing semiconductor substrate is of the same semiconductor type, e.g. p-type contacted by the back contact. This volume fraction is usually referred to as base. In the area of the surface of the front side of the semiconductor substrate is a thin layer of

CONFIRMATION COPY opposite type of semiconductor, eg n-type. This layer is commonly referred to as an emitter and the contacts contacting them as emitter contacts.

However, arranged on the front of the solar cell emitter contacts lead due to their associated partial shading of the front to a loss of efficiency. To increase the efficiency of the solar cell, it is basically advantageous to arrange both the base contacts and the emitter contacts on the back of the solar cell. For this purpose, corresponding emitter regions must be formed on the rear side of the solar cell. A solar cell in which both emitter regions and base regions are located on the side facing away from the light in use and in which both the emitter contacts and the base contacts are formed on the back, is referred to as a back contact solar cell.

To generate these emitter regions, that is to say of doped regions in solids, in particular in solar cells of monocrystalline or multicrystalline silicon, a high-temperature step is usually employed. The diffusion of the dopant, generally phosphorus, usually takes place in a diffusion furnace.

Also known for the doping of solids, instead of diffusion processes, for example, ion implantations, application and patterning of semiconductor layers by means of various coating methods such as Expitaxie, HeteroEpitaxie o.ä. A "laser doping of solids with a line-focused laser beam and production of solar cell emitters based thereon" (EP 1 738 402 B1) is known, in which a dopant is brought into contact with a surface of a solar cell, then an area by irradiation with a laser The surface of the solar cell is melted, wherein the dopant diffused into it and then recrystallized during the cooling of the molten area.Herein, the laser beam is focused in a line focus on the solid.

Also known is a "method for metallization of solar cells and its use" (DE 10 2006 044 936 B4), in which an aluminum foil with additional metallic Strukuren for interconnection in other semiconductor devices at least partially in direct contact, for example by pressing, blowing and / or Suction is brought to the surface of a solar cell and then at least partial bonding by at least partial melting of the aluminum with the surface of the semiconductor device is carried out by laser action, whereby a direct contact of the aluminum with the substrate force and / or positive fit is required Metallization can be applied as backside contact on the solar cell.

For the cost-effective production of solar cells, simple and fast individual process steps that can be integrated into a continuous production process are required. Above all, the production of back contactable solar cells needed however, a much higher proportion of process steps than standard solar cells. This is particularly due to the difficulty of making a local pn junction.

Against this background, the invention has for its object to provide a back-contact solar cell and a method for producing back-contact solar cells, with the insertion of individual simplifying process steps, the overall yield of production can be increased and a back contactable solar cell is easier to produce.

This object is solved by the features of claim 1 and of claim 6. The subclaims indicate advantageous embodiments of the invention.

The invention and its advantages

The invention has the advantage that in a conventional method, a further process step is introduced, in which a transparent, with a dopant (eg aluminum or boron) coated substrate, preferably a coated plastic film is brought into contact with the back of a silicon wafer and through Irradiation with a laser thereby locally a dopant is introduced, which forms a pn junction. Subsequently, according to the invention in a subsequent process step with the aid of a metal-coated film and a similar laser process, the base of the silicon, for. As an n-type silicon, contacted. In this case, a laser is used, which is preferably pulsed or provided with a line optics, so that the silicon is not permanently damaged.

The order of the process steps can thus look like this:

Etching a raw wafer of monocrystalline or multicrystalline silicon as a substrate, which is preferably, but not necessarily provided with an n-type doping. The alkaline or acidic etching process removes the sawing damage from the raw wafer and results in a textured surface with reduced reflection.

Injecting a layer of phosphorus into the n-type silicon. This is done for example in a tube furnace. In the p-type substrate, this step means the formation of a pn junction, in the n-type substrate, it leads to an n +, n front surface field.

Etching the resulting in the diffusion of phosphorus glass.

Etch back one side of the wafer about the depth of the diffused layer. This defines the back side of the future backside contact solar cell.

Absehe tion of an antireflection coating on the front of the wafer, which has an electrically passivating effect at the same time, but is not necessarily made of SiN; or applying a passivating layer and an anti-reflection layer one after the other.

Application of a Passivierschicht on the back of the wafer, for example, a dielectric layer, or even more of such layers.

It may be necessary for the passivation layer to be opened locally for the subsequent introduction of the dopant and / or the metallization. This is done with the aid of lasers or local etching by means of screen printing or inkjet processes.

Introducing a dopant by employing a transparent substrate, preferably a plastic film, which is coated, for example, but not necessarily, with a metal such as aluminum, boron, gallium or indium. This film is brought into contact with the coated side with the backside of the silicon wafer. A laser irradiates the vapor-deposited layer through the film. a) In this case, a known per se method, for example, the so-called LIFT method (Laser Induced Forward Transfer), are used. In this case, an optically transparent carrier material with a thin layer of the material to be applied is placed in front of a substrate to be coated. With the aid of a laser beam, the material to be applied is heated locally by the optically transparent carrier layer so much that it dissolves from the carrier material and deposits on the immediately adjacent substrate. At higher Load intensities, especially when using a pulsed laser, the material heats up so much that it reaches the evaporation point and that the transfer process to the substrate surface is supported and driven by the metal vapor pressure. b) In another embodiment of the invention, a metal-coated film is brought into contact with the silicon wafer surface as an alternative to the described LIFT method and then bombarded with a laser from behind through the film so that the metal is thereby blasted from the film and so is driven as a doping layer and not as metallization in the silicon. c) In a further embodiment of the invention, the film is not brought directly into contact with the silicon wafer, but some μπι placed away. As a result, after doping with the laser, the doping of the silicon wafer with the detached metal particles is achieved.

It is achieved by each of the described methods a), b), c) that a dopant is introduced locally and a pn junction is formed.

Basic contact tion of the n-type silicon wafer by a similar laser process using a metal-coated film. The metal of the coating may be silver or else a sequence of different metals, for example titanium, palladium, silver or other metals. After these additional steps according to the invention, some screen printing steps known from the production of silicon solar cells from the prior art could follow. The n-type and p-type regions should be contacted separately. The order of contacting is exemplified below:

Contacting the p-area with aluminum screen printing lines in a first step.

 Contacting the p-contacts with silver screen printing in a second step.

 Soldering of the contacts by printing an aluminum-silver paste on the edge over the aluminum screen print, which enables soldering of the contacts.

After each screen printing step, furnace processes for drying or sintering of the contacts are to be provided.

In a further advantageous embodiment of the invention, emitter areas or metallizations are applied completely or at least over a large area, for example, under the screen printing emitters and / or under the screen-printing metallization by means of laser technology.

In a further advantageous embodiment of the invention, the backside passivation is opened locally before the laser process.

In a further advantageous embodiment of the invention, the layout for optimizing the series resistance is changed such that the distance of the screen printing lines, the number and the location of the solderable areas; the width, length, spacing and shape of the emitter and contact lines are variable and adaptable to the respective requirements.

According to an additional embodiment of the invention, one or both structures produced by the laser can be galvanically or de-energized.

Further advantages and advantageous embodiments of the invention are the following description, the drawings and claims removed.

drawings

Fig. 1 shows the backside of the wafer after emitter formation.

In Fig. 2, the back side of the wafer after metallization is shown.

3 shows the back contact solar cell after emitter formation and screen printing.

Description of the embodiments

Fig. 1 shows the backside of the wafer 1 after emitter formation. The D-lines 2 consist of the locally driven dopant, z. As aluminum.

In Fig. 2, the back of the wafer 1 is shown after the metallization. The M-lines 3 represent the laser-transferred metal from the foil, e.g. Silver.

3 shows the back contact solar cell 4 after emitter formation and screen printing. In this case, the D-lines 2 represent the emitter (for example aluminum), the M-lines 3 the laser metallization, which are connected by M-screen-printing fingers 7 to the contact bar 5 at the edge. A silver / aluminum bar 6 is used for the solderable contacting of the emitter, which in turn is connected by D- Siebdruckfinger 8 with the lasered emitter regions.

The individual back contact solar cells can be connected together to form a string.

All in the description, the following claims and the drawings illustrated features may be essential to each other, both individually and in any combination with each other. LIST OF REFERENCE NUMBERS

1 wafer

 2 D-line from locally driven

 Dopant, e.g. aluminum

 3 M-line of laser-transferred metal from the foil, e.g. silver

4 back contact solar cell

 5 contact bars of laser metallization

6 silver / aluminum beams for soldering

 Contacting the emitter

 7 M screen printing finger

 8 D screen printing fingers

Claims

claims A back contact solar cell (4) having base contacts in contact with base regions and having emitter contacts in contact with an emitter layer, wherein both the base contacts and the base regions and the emitter contacts and the emitter layer are on the backside facing away from the light the back contact solar cell (4) are arranged, characterized in that in the emitter layer by means of a laser locally a dopant is introduced such that the emitter layer forms a pn junction to a base region. 2. rear contact solar cell (4) according to claim 1, characterized in that the emitter layer has a metallization, which can be applied by a laser, wherein the metallization of a contact to the base region is used. 3. rear contact solar cell (4) according to claim 1, characterized in that the dopant is aluminum or boron. 4. back contact solar cell (4) according to claim 2, characterized in that the metallization consists of silver or a sequence of metals. 5. rear contact solar cell (4) according to claim 2 or 4, characterized in that the sequence of metals contains at least one component titanium, palladium, nickel or silver. 6. A method for producing a back contact solar cell (4) according to claim 1, characterized in that a transparent substrate having a coating, with a coating side on the back of the back contact solar cell (4) is arranged and by irradiation with a laser the coating is detached from the substrate and is introduced locally as a dopant into the back contact solar cell (4). 7. The method according to claim 6, characterized in that the transparent substrate is formed as a plastic film. 8. The method according to claim 6 or 7, characterized in that the coating is formed of metal or boron. 9. The method according to claim 6, characterized in that in a further process step by means of a laser, a metal-coated film is irradiated so that a base region of a rear-side solar cell (4) is contacted. 10. The method according to claim 9, characterized in that the film is formed with a coating of silver. 11. The method according to claim 6, characterized in that the substrate is arranged in contact with the back contact solar cell (4) or at a distance from the back contact solar cell (4). 12. The method according to any one of claims 6 to 1 1, characterized in that the substrate or the film on the light-remote from the rear side of an emitter layer of the back contact solar cell (4) is arranged. 13. The method according to any one of claims 6 to 12, characterized in that the laser has a line optics and / or operated pulsed. 14. The method according to any one of claims 6 to 13, characterized in that a passivation layer is applied to the back of the back contact solar cell (4), then the dopant is introduced into the back contact solar cell (4) and the metallization of the back contact solar cell (4), followed by screen printing process steps.