EP2412008A1

EP2412008A1 - Method for producing solar cells having selective emitter

Info

Publication number: EP2412008A1
Application number: EP10711215A
Authority: EP
Inventors: Tobias Wuetherich; Jan Lossen; Mathias Weiss; Karsten Meyer
Original assignee: Ersol Solar Energy AG
Current assignee: Robert Bosch GmbH
Priority date: 2009-03-27
Filing date: 2010-03-26
Publication date: 2012-02-01
Also published as: US20120167968A1; CN102449738B; WO2010115730A1; DE102009041546A1; CN102449738A

Abstract

The invention relates to a method for producing solar cells having a selective emitter. Wafers (1) having no saw damage are first provided. A full-surface application of a doping source (2) to the wafer and a light, first inward diffusion of the dopant are then carried out until a first film resistor region is obtained. The applied doping source is then structured, wherein only those regions (4) remain as a result of the structuring that substantially correspond to the sections on the wafer to be contacted later. Another, second diffusion from the remaining regions of the doping source into the wafer volume is then carried out until a second film resistor region for the selective emitter (4) and a simultaneous redistribution of the dopant (5) introduced during the first diffusion are obtained, having the goal of lowering the dopant concentration in the region near the surface that is no longer covered by the doping source, under the condition that the film resistor values of the first film resistor region are larger than those of the second film resistor region.

Description

Process for the production of solar cells with selective emitter

description

The invention relates to a process for the production of solar cells with selective emitter.

At present, industrial solar cells are produced in the firing-through SiNx process. In this case, a homogeneous emitter with a layer or sheet resistance in the range of 40 to 80 Ω / D is generated on the cell front side by diffusion of phosphorus. On this layer, a further layer of silicon nitride is deposited, which serves to passivate and reduce the reflection. Subsequently, a contact grid of silver paste is applied. In a sintering step, the aforementioned paste is baked. Special ingredients in the silver paste allow the formation of an electrical contact between the contact grid and the actual emitter. A disadvantage of this type of contact formation is the need for a very high doping of the emitter in order to realize a sufficiently low contact resistance. This in turn has high losses in the areas between the trained contact fingers by recombination of the charge carriers result.

To address this disadvantage, so-called selective emitters for solar cells have been proposed. In these cells, only the contact region is highly doped, with the remainder of the wafer surface having a low doping.

One way of producing selective emitter structures is first of all to apply a diffusion mask, to open it at the desired locations, for example by printing an etching paste on certain areas or by laser ablation, in order then to carry out a high degree of diffusion into the volume of the wafer. Then the mask is to be removed and over the entire surface to realize a further diffusion with the aim of forming portions of lower doping.

In a further variant of the prior art, first a weak diffusion is carried out. According to AU 570 309, it is known first to perform a weak diffusion on the wafers over the entire surface. Subsequently, a very dense silicon nitride layer is applied by means of an LPCVD step, which serves both as a mask and later takes on the function of the anti-reflection layer. Trenches are then cut into the substrate by means of lasers. In these trenches into a strong doping is then made. The trenches in turn are subsequently metallized by nickel-copper-tin plating.

From DE 10 2007 035 068 Al a method for manufacturing a silicon solar cell with a selective emitter is previously known. In this method, in a first step, a planar emitter is produced on a surface of the substrate. This is followed by the application of an etching barrier to first portions of the emitter surface. This step is followed by an etching of the emitter surface in non-covered by the etching barrier second portions. After removal of the etching barrier, metal contacts are produced at the first subareas. It is described as advantageous in DE 10 2007 035 068 A1 that during the process, in particular during the etching of the emitter surface in the second partial regions, a porous silicon layer is formed, which is subsequently oxidizable. This oxidized porous silicon layer can subsequently be etched away together with optionally existing phosphorus glass. Using known screen printing and etching techniques, this method is said to be compatible with current industrial manufacturing equipment.

Summing up the teaching according to DE 10 2007 035 068 A1, the relevant idea is to first produce an emitter on at least one surface of a solar cell substrate with a homogeneous doping concentration high enough that it is suitable for contacting in the later screen printing process is. Directly thereafter, preferably before the deposition of an antireflection or passivation layer, first subregions of the already existing emitter surface are protected by an etching barrier. The unprotected areas are subject to the Etching step, so that the thickness of the emitter is reduced in the mentioned areas, with the result that in these second partial areas, an emitter is formed with an increased sheet resistance.

In the method for manufacturing a silicon solar cell with etched back emitter according to DE 10 2007 062 750 A1, in a first step, a planar emitter is produced on a surface of a solar cell substrate. Subsequently, a layer of porous silicon is created, which is then selectively subject to etching back. For the step of generating a planar emitter, any desired methods can be used according to DE 10 2007 062 750 A1. For example, it is possible to form the planar emitter by means of a POCl ₃ - Gasphaseπdiffusϊon by diffusing phosphorus from a hot gas phase in the surface of the substrate. The parameters when generating the flat emitter should be selected so that preferably sets an emitter layer resistance of less than 60 Ω / D. An etching barrier is applied to the created first subregions of the front surface of the substrate. The etch barrier protects the underlying first portions of the emitter surface from the etchant. The emitter surface is etched down so strongly in the etching step in the second subregions until a desired high sheet resistance of, for example, more than 60 Ω / D is stiffened in the remaining emitter layer. During the etching process, the sheet resistance is checked by measurement in order to be able to cancel the etching process in a targeted manner. In a further development of the method according to DE 10 2007 062 750 A1, an additional step takes place with regard to the production of the mentioned porous silicon layer. This process step takes place after the deposition of the etching barrier at the second partial regions of the emitter surface of the substrate which are not covered by the etching barrier. Instead of etching the emitter surface in the regions unprotected by the etching barrier, it is also possible here to use an etching process which leads to the formation of an at least partially porous silicon layer. This porous Siiiziumschicht is oxidized at a later process step.

The photovoltaic cell with two or more selectively diffused regions according to DE 697 31 485 T2 assumes that the selective regions are produced by means of a single diffusion step. In order to be able to create differently selectively diffused regions on the semiconductor substrate with different dopant levels, a screen printing of solid-based dopant pastes is assumed in order to then form the diffusion regions with a first high-temperature heat-curing step. After screen printing of a metal paste for the contact fingers, a second high-temperature heat treatment step is performed.

The state of the art is still on R.E. Schlosser et al., "Manufacturing of Transparent Select® Emitter and Boron Back-Surface Solar Cell Using Screen Printing Technique", 21st European Photovoltaic Solar Energy Conference, 4-8 September 2006, Dresden.

From the above-described solutions of the prior art, various disadvantages arise.

Homogeneous emitters, as they are usually used in industrial manufacturing so far, have relatively poor optical and electronic properties. In order to achieve a sufficiently low contact resistance, much more doping is required than is necessary for a sufficient electrical function per se. The too high doping is noticeable as too high emitter saturation current, which has a negative influence on the open clamping voltage and the filling factor. Due to the low charge carrier lifetime in the highly doped emitter, charge carriers generated there can not be separated, which leads to a reduction in the short-circuit current and ultimately results in a reduced efficiency of the solar cell.

The proposed methods for producing selective emitters avoid the abovementioned disadvantages at least occasionally, but are not suitable for cost-effective industrial implementation for various reasons.

The explained method with masking and two diffusion steps involves very many process steps and is therefore cost-intensive.

The use of a mask to open the area to be contacted later is less economical in that more than 80% of the area to be covered with an etching mask, such as an etching varnish, which also leads to high costs.

The opening with a screen-applied etching paste or by laser ablation on the one hand entails an increased safety expenditure when using aggressive paste materials and on the other hand a strong damage to the surface during treatment by laser ablation.

Although the solution according to DE 10 2007 035 068 Al reduces the need for Abdecklack. The disadvantage, however, is that the sheet resistance in the low-doped region is produced by back etching. However, the etching processes outlined there are not self-limiting. Inhomogeneities of the etching bath such as temperature, concentration of the etching medium or the degradation products therefore lead to an inhomogeneity of the sheet resistance, which adversely affects the cell efficiency. The etching solutions necessary there are extremely aggressive, which makes it difficult to choose a suitable masking varnish. In addition, the emitter profile produced after etchback still has too high a surface concentration of the dopant, resulting in an undesirably high emitter saturation current.

From the foregoing, therefore, it is an object of the invention to provide a further developed method for producing selective emitter solar cells, which as a result serves to provide solar cells having a higher energy conversion efficiency, and wherein the amount of necessary masking materials is reduced.

The object of the invention is achieved by a method according to the teaching of claim 1, wherein the dependent claims represent at least expedient refinements and developments.

According to the method, there is provision of saw-damage-free wafers. If necessary, the wafers on their front side can have texturing carried out in a manner known per se. Under front side is here to understand the side that is exposed to the solar cell during later use of the solar cell. The wafer treated in this way is then provided with a full-surface doping source. During the application of the full-area doping source and subsequently thereto, an easy, first introduction of the dopant is achieved until a first sheet resistance region is reached.

Subsequently, the doping source is patterned, wherein as a result of the structuring only those areas remain which substantially correspond to the sections to be contacted later on the wafer or by a deliberately predetermined small amount are larger than these contact portions.

This is followed by carrying out a further, second diffusion from the remaining regions of the doping source into the wafer volume until a second sheet resistance region for the selective emitter has been achieved. In this further, second Dϊffusionsschritt simultaneously redistributes the introduced during the first diffusion of dopants with the aim of lowering the doping concentration in the near-surface areas, which are no longer covered with the doping, under the proviso that as a result of this treatment Sheet resistance values in the first sheet resistance range are greater than those of the second sheet resistance range.

The doping source preferably comprises phosphosilicate glass (PSG).

The first sheet resistance range is after completion of the two diffusions at substantially 100 to 300 Ω / D. The second layer resistance region for the emitter section below the later contacts is between 30 Ω / D and less than 100 Ω / D.

The structuring of the doping source takes place in that etching-resistant masking is applied to the areas to be left, with subsequent execution of the etching step.

The masking may be formed by screen printing, stencil printing, hot melt screen printing, ink jet printing, dispensing, aerosol printing, hot melt ink jet printing or the like.

After the etching step, the etching mask is removed. The etching process can be carried out wet-chemically or under plasma or plasma-assisted, wherein after the etching step the masking layer and any residues are stripped or ashed by creating an oxygen plasma.

As an additional process step, oxidation of the surface of the wafer is possible in order to bring about a further lowering of the surface concentration as well as an injection of interstitial oxygen atoms into the wafer.

The invention will be explained below with reference to an embodiment and with the aid of a figure.

The figure shows a basic sequence of steps a) to f) with the aim of forming a selective emitter by structuring the doping source to the front side metallization, wherein the processing of the back can be done by any method of the prior art.

In the method for producing a selective emitter having special features by additionally driving from patterned source according to the embodiment, on the saw damage etched and possibly textured wafer, a doping source, e.g. Phosphosilicate glass (PSG) applied and slightly diffused (Fig. Ia)). The silicon wafer is here provided with reference numeral 1 and the full-surface applied diffusion source with the reference numeral 2. The slightly diffused region is indicated by the reference numeral 5.

For example, in this step, a sheet resistance between 100 and 200 Ω / π is set. This can be done in a combined process step of gas phase diffusion, e.g. Phosphoroxyl chloride (POCb) and heat treatment done, for example in a quartz tube furnace.

It is likewise possible to generate the doping source, eg PSG, by means of Atmospheric Plasma Chemical Vapor Deposition (APCVD) and then to carry out the first, light diffusion step in a tubular or continuous furnace with roller, chain belt or lifting beam transport. Subsequently, the applied full-surface diffusion source 2 is structured, so that strip-shaped regions 3 remain, as shown in FIG. Ib) greatly simplified.

The structuring of the doping source takes place in such a way that the area which is to be electrically later contacted is still covered by the source material, but all other areas are no longer covered. For technological reasons, the source material may also be left slightly above or below this later contact area.

The above-mentioned structuring of the doping or diffusion source can be achieved by various methods.

For example, the regions in which the source layer is to remain are masked by an etch-resistant layer. Suitable etching-resistant layers include, but are not limited to, organic, dry-crosslinking paints, waxy organic materials, UV-curing paints, as well as silicon-oxide-nitride films prepared by annealing starting materials of this type.

The masking areas or sections may be realized by screen printing, stencil printing, hot melt screen printing, ink jet printing, hot melt ink jet printing, dispensing, aerosol printing or the like.

Subsequently, in the unmasked regions, the diffusion source is removed by etching, wherein here advantageously an etching medium is selected, which etches the diffusion source with a high selectivity with respect to the silicon-based material of the wafer.

For PSG, for example, a wet-chemical etching in hydrofluoric acid (HF) is recommended. Hydrofluoric acid etches PSG extremely fast, but silicon hardly.

Alternatively, acids with the same property can be used in a wet-chemical etching. Likewise, however, a plasma step in the sense of dry etching can also be used. Here too, fluorine ion-based etching processes, eg with CF ₄ , have a selectivity necessary for the PSG layer removal. After this treatment, the masking layer is removed. This can then be done in the same etching plant in which the diffusion source was removed. Organic layers can be removed wet-chemically by suitable stripper solutions. Silicon oxide-nitride layers can be etched with phosphoric acid.

If the etching of the swelling layer by plasma, so then an oxygen plasma for the ashing of organic substances or layers can be used.

Further possibilities for structuring the diffusion source are the application of etching pastes in the areas in which the swelling layer is to be removed, or the dry etching by etching masks.

In a second diffusion step, shown with the Fig. Ic), formed below the local diffusion source 3, a strong doping 4 in the wafer 1 from. All other areas have a weak doping 5b.

Thus, in the second diffusion process in the regions in which there is still a diffusion source, an emitter with low sheet resistance is produced, which is very well suited for later contacting.

In the areas in which there is no longer any swelling layer as dopant, on the other hand, only the dopant that has already diffused into the silicon is redistributed. This leads advantageously to a lowering of the Dotierkonzentratioπ 5b in the near-surface region. This reduction is targeted and intended and thus very advantageous for the solar cell, as it can produce an emitter with a lower emitter saturation current density.

Also, the surface passivation can be performed more effectively at a lower doping concentration at the surface. The diffusion may e.g. by temperature treatment in a quartz tube furnace or in a continuous furnace.

By adjusting the gas composition, for example by adding oxygen or water vapor in the oven, an additional oxidation of the swelling layer and the Quellschϊcht-free surface can be done. This allows a further reduction of the surface concentration. The oxidation can also accelerate the diffusion.

Fig. Id) shows the situation after the removal of the remaining diffusion sources. 3

Fig. Ie) symbolically represents an applied antireflection layer 6.

The preparation of the antireflection layer 6, the implementation of the edge insulation and the production of the metallization contacts 7 (see FIG. 1)) can be carried out by different methods known per se. When applying the front-side contacts 7, care must be taken to ensure that the intended contact areas (heavy doping 4) are maintained.

As a result of carrying out the method, it is possible to reduce the recombination of free charge carriers in the emitter, so that a higher current can be generated and consequently the efficiency of such solar cells is subject to an improvement.

Also, the emitter can passivate better. This and the cheaper doping profile reduce the emitter saturation current, which in turn increases the no-load voltage of the solar cell. Finally, the contact resistance of the front side metallization to the emitter can be reduced.

The method described is characterized by a particular simplicity and manageable process management. Only a small part of the surface of the wafer needs to be masked, so less masking material is needed. For masking conventional diffusion sources, a variety of readily controllable materials comes into question. The etching of e.g. PSG as Dotϊerquelle can be carried out with hydrofluoric acid in a very cost-effective manner and easily controlled. The mentioned diffusion processes are relatively short and feasible at moderate temperatures. This saves energy and allows the process to be used on a wide range of silicon feedstock and wafers made from it. This also applies to wafers in which an excessively high temperature budget would lead to a reduction in the service life.

Claims

claims

1. A process for the production of solar cells with selective emitter, comprising the following steps:

Providing a saw-damage-free wafer,

full-surface application of a doping source to the wafer as well as easy first penetration of the dopant until reaching a first sheet resistance region,

Structuring of the applied doping source, as a result of structuring only those areas remain which substantially correspond to the sections to be contacted later on the wafer,

Performing a further, second diffusion from the remaining regions of the doping source into the wafer volume until a second layer resistance region for the selective emitter is obtained and simultaneously redistributing the dopant introduced in the first diffusion with the aim of lowering the doping concentration in the near-surface region is no longer covered by the doping source, provided that the sheet resistance values of the first sheet resistance region are larger than those of the second layer stagnation region.

2. The method according to claim 1, characterized in that the doping source comprises phosphosilicate glass (PSG).

3. The method according to claim 1 or 2, characterized in that the first sheet resistance range after the second diffusion step is substantially between about 100 to 300 Ω / D.

4. The method according to any one of the preceding claims, characterized in that applied to the structuring of the doping source on the remaining areas an etch-resistant masking and then at least one etching step is performed.

5. The method according to claim 4, characterized in that the masking by means of screen printing, stencil printing, Holt-Melt Sϊebdruck, inkjet printing, dispensing, aerosol printing; Hot-melt ink-jet printing or the like techniques is formed.

6. The method according to claim 4 or 5, characterized in that the etching mask is removed after carrying out the etching step.

7. The method according to any one of claims 4 to 6, characterized in that the etching process is performed plasma-assisted, wherein following the etching step, the masking layer and existing organic deposits are ashed by treatment by means of oxygen plasma.

8. The method according to any one of the preceding claims, characterized in that an oxidation of the surface of the wafer takes place in order to effect a further reduction of Oberflächenkonzeπtration and / or an acceleration of the diffusion.

9. The method according to any one of the preceding claims, characterized in that the second sheet resistance range between 30 and <100 Ω / α.

10. Solar cell, produced by a process according to at least one of the preceding claims.