DE102011112043A1 - Process for producing a photovoltaic solar cell - Google Patents

Abstract

The invention relates to a method for producing a photovoltaic solar cell, comprising the following method steps: A providing a semiconductor structure (4), which semiconductor structure (4) comprises a silicon layer and is a precursor in the production process of a photovoltaic semiconductor solar cell, B generating at least one pn junction in the semiconductor structure (4), C applying at least one metallic contacting structure (1, 6) to a contacting surface of the semiconductor structure (4) for electrically contacting the semiconductor structure (4) and D thermal treatment by applying temperature to at least the semiconductor structure (4) and the applied contacting structure (1, 6) for a period in the range of 1 second to 60 minutes at a temperature in the range 200 ° C to 800 ° C, which is characterized in that in step D, the thermal treatment is carried out in a gas atmosphere, which is less than 15 % Sow and more than 1% of water vapor.

Description

The invention relates to a method for producing a photovoltaic solar cell according to the preamble of claim 1.

A photovoltaic solar cell constitutes a planar semiconductor component in which charge carrier pairs are generated by means of falling electromagnetic radiation and separated, so that a potential is created between at least two metallic contacting structures and electrical power can be tapped from the solar cell via an external electric circuit connected to these contacting structures , The charge carrier separation takes place at a pn junction, which can be realized, for example, by doping a doping type opposite thereto to form an emitter in a silicon substrate of a basic doping type. It is also known to form the emitter by applying one or more layers on a base substrate.

The invention relates to methods for producing such photovoltaic solar cells, in which at least the base is formed as a silicon layer. Such a layer may be formed for example by a silicon substrate such as a silicon wafer or by a silicon layer on a carrier substrate.

For the production of a solar cell, a semiconductor structure is provided, which semiconductor structure comprises a silicon layer as described above and thus is a precursor in the production process of a photovoltaic semiconductor solar cell. Subsequently, at least one pn junction is generated in the semiconductor structure. Here and below, the term pn junction designates both those semiconductor structures in which opposite doping regions adjoin one another directly, and those structures in which an opposite dopants are separated by a thin, intrinsic or dielectric layer and nevertheless forms a pn junction, z. As a so-called PIN transition. Furthermore, surface charge induced pn junctions of metal insulator semiconductor layer systems can be used. All variants are referred to below as the pn junction.

Subsequently, at least one metallic contacting structure is applied to a contacting surface of the semiconductor structure for electrical contacting of the semiconductor structure. By means of the metallic contacting structure, charge carriers of the emitter or base region are removed during operation of the solar cell.

In many manufacturing processes, a temperature treatment of the semiconductor structure, which represents a precursor of a solar cell in the manufacturing process, is necessary or at least useful, for example to improve the properties of electrically passivating layers and / or properties of contacts and / or to heal crystal damage in the silicon material ,

It is known to carry out this "annealing step" temperature treatments under Formiergasatmosphäre, compressed air or nitrogen atmosphere.

In a variety of today's photovoltaic solar cell manufacturing processes, printed and subsequently contact-fired silver contacts are used as the metallic contacting structure. In this case, the temperature treatment carried out after the contact firing causes a redistribution of a thin layer of glass frit, which is located in the production process of the metallic contact structure between the silicon layer and the crystallites of the contact structure. In this case, gaps are formed and there is the disadvantage that the specific contact resistance between the contacting structure and silicon increases. This is for example in S. Kontermann, A. Grohe, and R. Preu, "Detailed analysis of annealing silver front side contacts on silicon solar cells", Proceedings of the 33rd IEEE Photovoltaic Specialists Conference, San Diego, CA, USA, 2008, pp. 1-5 described.

It has therefore been assumed that advantageously the temperature treatment is carried out under Formiergas atmosphere. For in comparison, for example, to carry out the temperature treatment under a nitrogen atmosphere, the above-described negative influence on the contact resistance is reduced in forming gas, such as in G. Schubert, J. Horzel and S. Ohl, Proceedings of the 21st European Photovoltaic Solar Energy Conference, Dresden, Germany, 2006, Investigations on the Mechanism Behind the Beneficial Effect of a Gasketing on Solar Cells with Silver Thick Film Contacts , pp. 1460-6 described.

For example, manufacturing processes are known in which the aforementioned temperature treatment is carried out under a Formiergasatmosphäre consisting of about 95% N ₂ and 5% H ₂ .

Due to the risk of explosion when using hydrogen gas in conjunction with elevated temperatures, a complex system design is necessary to carry out such processes in order to ensure the necessary safety standards. In addition, the use of Formiergas is costly.

Further, it is known that water vapor can be used as the atmosphere during a tempering step to lower the surface recombination velocity at an Si-SiO ₂ interface, wherein the SiO ₂ layer is formed by thermal oxidation of a silicon substrate, as described, for example Y. Abe, H. Nagayoshi, T. Kawaba, N. Arai, T. Saitoh, K. Kamisako, "Effect of High Temperature Steam Annealing for SiO 2 Passivation", Solar Energy Materials and Solar Cells 65 (2001), 607-612 ,

US Patent US006136728A such as Xiewen Wang, Mukesh Khare and TP Ma, "Effects of Water Vapor Anneal on MIS Devices Made of Nitrided Gate Dielectrics", Symposium on VLSI Technology, Digest of Technical Papers, 1996, 226-227 describe a temperature treatment of a semiconductor device in a water vapor atmosphere. This device has a metallization, and a nitrogen-containing dielectric layer with a mole fraction of at least 1%.

The present invention is therefore an object of the invention to provide a method for producing a photovoltaic solar cell, in which the aforementioned thermal treatment is less expensive and less expensive to carry out.

This object is achieved by a method according to claim 1. Advantageous embodiments of the method can be found in claims 2 to 12. Hereby, the wording of all claims is explicitly incorporated by reference in the description.

The method according to the invention for the production of a photovoltaic solar cell comprises the following method steps: in a method step A, the provision of a semiconductor structure takes place, which semiconductor structure comprises a silicon layer. The semiconductor structure thus represents a preliminary stage in the production process of a photovoltaic semiconductor solar cell.

It is within the scope of the invention that the semiconductor structure is formed as a silicon wafer. It is likewise within the scope of the invention that the semiconductor structure comprises a carrier substrate on which a silicon layer is arranged.

In a method step B, at least one pn junction for charge carrier separation is generated in the semiconductor structure. Here, it is within the scope of the invention, as mentioned above, to form the pn junction by means of directly adjacent doping regions with opposite dopings (dopings are the n-doping and the p-doping opposite thereto) and / or by interposing a thin intrinsic or dielectric layer form a so-called pin junction, and / or form by surface charges an induced pn junction, which are also defined below as falling under the generic term pn junction.

In this case, it is within the scope of the invention to form the pn junction in a manner known per se. For example, this is possible by doping corresponding semiconductor layers or a silicon wafer with corresponding dopants. Likewise, the application of differently doped and / or stationary charges having layers to form a pn junction in the invention.

In a method step C, at least one metallic contacting structure is applied. The contacting structure is used for electrical contacting of the semiconductor structure, so that charge carriers can be dissipated via the metallic contacting structure during operation of the solar cell and exposure to the same with electromagnetic radiation.

In this case, it is within the scope of the invention to apply at least two metallic contacting structures in a manner known per se, a first metallic contacting structure serving for electrical contacting of a base produced in method step B and a second metallic contacting structure for electrically contacting an emitter produced in method step B.

In a method step D, a thermal treatment takes place by applying temperature to at least the semiconductor structure and the applied metallic contacting structure. The thermal treatment is carried out for a period in the range of 1 second to 60 minutes at a temperature in the range 200 ° C to 800 ° C.

It is essential that in process step D the thermal treatment is carried out in a gas atmosphere which has less than 15% oxygen and more than 1% water vapor. The percentages for the description of the gas atmosphere here and below - unless stated otherwise - refer to the molar ratio, ie the proportion of the molecules of the designated gas per unit volume to the total number of gas molecules per unit volume.

The invention is based on the Applicant's finding that, surprisingly, a positive effect increasing the efficiency of the solar cell results when carrying out method step D as described above. So far it was assumed that a Steam atmosphere corrosive acts and at a temperature treatment of a solar cell or a precursor in the production process of a solar cell under such an atmosphere, a negative impact on, for example, an increase in series resistance z. B. in the contacting area, so that the fill factor and thus the efficiency of the solar cell is reduced. It has hitherto been assumed that a temperature treatment under a steam atmosphere would result in corrosion of the metal contacts, in particular in the case of solar cells. Since, due to the high current densities to be dissipated, the metal contacts represent an essential and critical component of a photovoltaic solar cell, such a process condition in solar cell production has hitherto been explicitly avoided on account of the expected negative influence on the efficiency of the solar cell.

Surprisingly, contrary to this prevailing opinion, however, the thermal treatment in process step D can be carried out in a gas atmosphere containing steam, provided that the oxygen content is less than the previously stated 15%.

The method according to the invention thus makes it possible for the first time to carry out a thermal treatment according to method step D that is more cost-effective and, with regard to the process conditions compared with the use of the above-mentioned forming gas, safer, by carrying out the desired efficiency-increasing effects.

The previously assumed adverse effect in the thermal treatment in a gas atmosphere containing oxygen and water vapor is sufficiently suppressed even at the aforementioned upper limit of 15% for the proportion of oxygen in the gas atmosphere. Preferably, in process step D, the oxygen content of the gas atmosphere is selected to <5%, preferably <500 ppm, in particular <100 ppm, in order to ensure an even stronger suppression of the aforementioned undesired efficiency-reducing effect.

To achieve the positive effects in process step D of the process according to the invention, in addition to the proportion of water vapor> 1% of the gas atmosphere and the proportion of oxygen <15% of the gas atmosphere, no further reactive gases are absolutely necessary.

In method step D, the gas atmosphere therefore preferably has, apart from oxygen and water vapor, further reactive gases only in a proportion of <10%, preferably <5%, in particular <1%. As a result, adverse effects are avoided by other reactive gases or excluded. In particular, it is therefore advantageous that the reaction atmosphere additionally has only inert gas in process step D of the process according to the invention, apart from oxygen and water vapor. Preferably, the inert gas comprises at least one of the gases N ₂ , CO ₂ , Ar or other noble gases.

In the method according to the invention, it is thus no longer necessary to introduce gaseous hydrogen into the gas atmosphere in process step D. Preferably, in method step D, the gas atmosphere therefore has a hydrogen content <3%, more preferably <1%, in particular <0.5%.

It can be assumed that the efficiency-increasing effect of process step D in the process according to the invention is attributable to a reaction which is based or prevented by the water vapor in conjunction with reduced oxygen content. Positive effects occur, for example, through one or more of the following mechanisms:
If the solar cell has dielectrically passivated surfaces, the treatment results in an improvement of the passivation effect. It is known, for example, that in the case of thermally grown silicon oxide layers which are covered with an aluminum layer, the treatment achieves a reduction in surface recombination. This is generally referred to as Alneal and is for example in AS Grove, "Physics and technology of semiconductor devices," John Wiley & Sons, Inc., New York, 1967 described.

It is also known that a temperature treatment can reduce the specific contact resistance of a metal-semiconductor contact, which has a positive effect on the fill factor and thus the efficiency of the solar cell. In galvanically deposited or reinforced contacts, it is known that temperature treatment improves contact properties and, for example, causes formation of a metal silicide at the metal-semiconductor interface, which increases mechanical adhesion and lowers the specific contact resistance, such as in FIG K. Maex, M. Van Rossum, "Properties of metal silicides", Inspec, London, UK, 1995 described.

If the solar cell has local laser alloyed contacts (LFC), such as in " DE 100 46 170 A1 Or R. Preu, E. Schneiderlöchner, S. Glunz, R. Lüdemann, PCT / EP01 / 10029 Thus, the treatment of temperature causes a reduction of the charge carrier recombination at the contact since crystal damage is healed.

Investigations by the Applicant have furthermore shown that in method step D, the gas atmosphere preferably contains less than 90%, more preferably less than 70%, in particular less than 50% steam. This is due to the fact that supply lines and the process chamber otherwise subject to increased corrosion.

Investigations by the applicant further showed that in the method according to the invention an optimization of the efficiency of solar cells with screen-printed silver front contacts and passivated back is achieved by heating in step D, a temperature in the range 200 ° C to 500 ° C, preferably in the range 250 ° C to 450 ° C takes place. This is because if the temperatures are too low, the above-mentioned positive effects are not strong enough. At too high temperatures, negative effects such as increasing the specific contact resistance of the screen printed silver contacts to the emitter, such as in S. Kontermann, A. Wolf, D. Reinwand, A. Grohe, D. Biro and R. Preu "Optimizing Annealing Steps for Crystalline Silicon Solar Cells with Screen Printed Front Side Metallization and on Oxide-Passivated Rear Surface with Local Contacts", Progress in Photovoltaics 17, 2009, pp. 554-66 described.

It has also been found in these studies that preferably in process step D solar cells with screen-printed silver front contacts and passivated back heating for a period of time in the range 30 seconds to 10 minutes. This is due to the fact that if the process times are too short, the above-mentioned positive effects are not strong enough. If the process times are too long, negative effects such as the increase in the specific contact resistance of the screen-printed silver contacts to the emitter, such as in S. Kontermann, A. Wolf, D. Reinwand, A. Grohe, D. Biro and R. Preu "Optimizing Annealing Steps for Crystalline Silicon Solar Cells with Screen Printed Front Side Metallization and on Oxide-Passivated Rear Surface with Local Contacts", Progress in Photovoltaics 17, 2009, pp. 554-66 described.

The temperature is applied in method step D of the method according to the invention at least in the semiconductor structure and the applied contacting structure. Preferably, however, the entire precursor of the photovoltaic solar cell is subjected to temperature, in particular preferably by methods known per se:
In this context, it is within the scope of the invention to subject the preliminary stage of the photovoltaic solar cell to an oven for thermal treatment, particularly preferably in a continuous furnace, so that simple integration into a process line in the production of a photovoltaic solar cell is possible. This can be resorted to known flow furnaces. Particularly advantageous is a continuous furnace with lifting cord transport, as described in "Patent DE 100 59 777 B4 " and " D. Biro, G. Emanuel, R. Preu, and G. Willeke, High-capacity walking string diffusion furnace, at PV in Europe - From PV Technology to Energy Solutions, Rome, Italy, 303-6 (2002) "Or with roller transport to minimize thermal bridges at the entrance and exit of the furnace by thermal masses of the means of transport. The cords or rollers transporting the preliminary stage of the photovoltaic solar cell can be made of ceramic (in particular containing aluminum oxide, silicon oxide), glass, glass fiber or glass ceramic, carbon fiber material, Sikrabond, metal or plastic (especially for low temperatures) or composite materials.

Likewise, the use of a transport mechanism based on metal chain belts, carbon fiber material tapes, glass or glass ceramic, textile tapes, plastic tapes, synthetic fiber tapes and / or composite materials or the like is within the scope of the invention. Likewise, the use of tube ovens or rapid thermal processing (RTP) furnaces is within the scope of the invention.

The aforementioned ovens preferably have gas locks in order to prevent the introduction and removal of the precursor of the photovoltaic solar cell gas exchange with the environment. In particular, the use of so-called nitrogen locks, in which by gas flow of N ₂ gas curtains are formed, in a conventional manner advantageous.

The generation of the water vapor to form the gas atmosphere in process step D of the process according to the invention can be carried out in a conventional manner, in particular is a pyrolytic production, an evaporation of ultrapure water, a generation by means of a steamer and / or by passing N ₂ by ultrapure water in one so-called bubblers advantageous, or by water is evaporated directly in the oven to achieve a high degree of purity of the generated water vapor. Investigations by the Applicant have shown that, in particular, steamer systems are advantageous, since they ensure very high degrees of purity in the production of water vapor. In particular, the use of a steamer system according to US 7618027 is advantageous.

Method step D is preferably carried out in a gas-tightly sealed process chamber, in particular the embodiment is located in a process chamber within the scope of the invention, which has at one or more openings aforementioned gas curtains.

Therefore, method step D is preferably carried out in a process chamber or a process area of a furnace, which chamber or process area is purged before the temperature is applied and / or before the introduction of the preliminary stage of the photovoltaic solar cell. Here, the rinsing is preferably carried out by means of an inert gas and particularly preferably by means of N ₂ .

The temperature is applied in method step D such that the side of the semiconductor structure or the entire precursor of the photovoltaic solar cell, which faces the light after passing through all process steps as a manufactured solar cell, is oriented upward. Optionally, the side facing away from the light can also be oriented upward or the semiconductor structure or the entire preliminary stage of the photovoltaic solar cell can be aligned otherwise.

The inventive method is basically applicable to previously known methods for producing a solar cell, which comprise the aforementioned method steps A to D. This includes a large number of production variants and different solar cell structures produced. Of course, it is within the scope of the invention to precede, follow or interpose further method steps in the abovementioned method steps A to D.

Investigations by the Applicant have shown that, in particular in production processes for solar cells in which the metallic contacting structure is produced by screen printing in process step C, the process according to the invention has a favorable effect on the achieved efficiency of the solar cell. In particular, it is advantageous that, in method step C, the metallic contacting structure is produced by applying a screen-printing paste which contains metal particles and particularly preferably additionally glass frit. This screen-printed contact structure can optionally be reinforced by chemical metal deposition before or after process step D.

In particular, the use of the method when using screen-printing pastes is advantageous, which screen printing pastes are formed in a high-temperature step after application of the paste, preferably at temperatures in the range 700 ° C to 900 ° C, by a layer located under the paste, in particular a electrically passivating layer, preferably a dielectric layer, penetrate therethrough. Such pastes are also referred to as "firing pastes".

Advantageously, after forming the contact structure, a reinforcement thereof, preferably by means of galvanic reinforcement.

Optionally, for screen printing technology, in method step C, the metallic contacting structure can likewise be applied by stencil printing, dispensing, inkjet printing, aerosol printing, pad printing and / or web printing, as well as a combination thereof with screen printing technology.

The thermal treatment, as described above, improves the properties of the metal-semiconductor contact. This expressly includes metal contacts which have been produced by means of sputtering, evaporation or chemical deposition from metal-containing baths and at least partially contain aluminum and / or nickel and / or silver and / or copper or a layer system and / or an alloy of titanium, palladium, silver, Represent chromium, vanadium, nickel and / or aluminum.

The formation of local structures for contacting the base may alternatively be described by the so-called i-PERC approach, as described in, for example, in the LFC technology already described. US2009 / 0301557A1 "Or" G. Agostinelli, P. Choulat, HFW Dekkers, S. De Wolf, and G. Beaucarne, Screen Proofs large area crystalline silicon solar cells to thin substrates, in Proceedings of the 20th European Photovoltaic Solar Energy Conference, Barcelona, Spain, 647- 50 (2005) "As well as by means of printed pastes, which form an electrically conductive contact to the base during the subsequent contact firing through a dielectric layer or a layer system comprising a plurality of dielectric layers.

As mentioned above, the thermal treatment in process step D also has a favorable effect on the electrical passivation properties of a passivation layer. Preferably, in the method according to the invention, therefore, prior to method step D, at least one dielectric layer is applied to at least one side of the semiconductor structure in order to reduce the recombination speed on this side of the semiconductor structure.

If a dielectric layer or a system composed of a plurality of dielectric layers arranged one above the other is used, and if this or this is located on the side of the semiconductor substrate that corresponds to the side facing away from the light in the finished solar cell, then the total thickness of this layer or layer system is preferred more than 50 nm, more preferably more than 100 nm, particularly preferably more than 200 nm.

If a dielectric layer is constructed as a thermal oxide layer, then the thermal oxidation process can take place before or after the formation of the texture, as well as before or after Deposition of a layer of silicon nitride, which may also be formed as an antireflection layer, as well as carried out simultaneously with other process steps.

The formation of the dielectric layer preferably takes place by means of a SiNTO, FeDiO or TOPAS process sequence. These process sequences themselves are, for example, in " O. Schultz, A. Mette, M. Hermle and SW Glunz, Thermal Oxidation for Crystalline Silicon Solar Cells Exceeding 19% Efficiency Applying Industrially Feasible Process Technology, Prog. Photovolt: Res. Appl. 2008; 16: 317-324 ", Hereinafter referred to as the FeDiO sequence," S. Mack, U. Jäger, A. Wolf, S. Nold, R. Preu and D. Biro, SIMULTANEOUS FRONT EMITTER AND REAR SURFACE PASSIVATION BY THERMAL OXIDATION - TO INDUSTRIALALLY FEASIBLE APPROACH TO A 19% EFFICIENT PERC DEVICE, 25th European Photovoltaic Solar Energy Conference and Exhibition, Valencia, Spain, 2218-2222, 2010 ", Hereinafter referred to as TOPAS sequence, or" A. Wolf, A. Walczak, S. Mack, EA Wotke, A. Lemke, C. Bertram, U. Belledin, D. Biro, and R. Preu, THE SINTO PROCESS: UTILIZING A SINX ANTIREFLECTION LAYER FOR EMITTER MASKING DURING THERMAL OXIDATION, Proceedings of the 34th IEEE Photovoltaic Specialists Conference, Philadelphia, PA, USA, 534-539, 2009 ", Hereinafter referred to as SiNTO sequence described.

The dielectric layer may also be formed as silicon nitride, silicon oxide, aluminum oxide, amorphous silicon, silicon carbide or silicon oxynitride or as a layer system of these.

Process step D is preferably carried out after process steps A, B and C. In particular, it is preferred to carry out the method steps in the inventive method in the order A, B, C, optionally with the interposition of further intermediate steps. In particular, method steps can also be combined and carried out at the same time.

Further advantages and properties of the present invention will be explained below with reference to an embodiment and the figures. Showing:

1 a partial section of a schematic representation of a solar cell, which was produced with an embodiment of the method according to the invention and

2 an embodiment of the method according to the invention as a process flowchart.

1 shows a schematic representation of a solar cell of a photovoltaic solar cell. This is made of a semiconductor structure 4 formed, which consists essentially of a p-doped silicon wafer. At the in 1 At the top, which faces the light when the solar cell is in operation, a texturing is formed to increase the incidence of light. At this front is still a phosphorus-doped emitter 3 is formed, which thus forms a pn junction at the boundary to the p-doped region of the silicon wafer.

To reduce the reflection as well as the electrical passivation, that is reducing the surface recombination speed of the front is a dielectric layer 2 applied, which is formed as a silicon nitride layer.

Furthermore, on the front side by screen printing a metallic contacting structure 1 designed as Vorderseitenmetallisierung. The Vorderseitenmetallisierung has the known double comb shape, wherein in 1 only sections of two fingers of the double comb shape can be seen, which fingers are in 1 extend perpendicular to the plane of the drawing.

At the rear, a thermally grown silicon oxide layer is also used to reduce the surface recombination rate 5 arranged.

On the thermal oxide layer over the entire surface of an aluminum layer is arranged, which pointwise (see example reference numerals 7 ) the thermal oxide layer 5 penetrates.

At the areas where the contacting structure 1 covering the front is not a dielectric layer 2 educated.

Accordingly, the emitter is 3 thus electrically conductive with the metallic contacting structure 1 and the base of the semiconductor structure 4 electrically conductive with the formed as rear side contacting metallic contacting structure 6 connected.

In the 1 illustrated solar cell was produced by means of an embodiment of a method according to the invention, which embodiment schematically in 2 is shown.

First, in step A, the semiconductor structure 4 consisting essentially of the p-doped silicon wafer in (100) orientation.

This was followed by preconditioning, comprising the following process steps: removal of the near-surface sawing damage in an alkaline etching solution, followed by wet-chemical cleaning of the silicon surface.

By means of a thermal oxidation, the thermal oxide layer became 5 applied on the back. A thermal oxide layer which also forms on the front side was subsequently removed again.

This was followed by an alkaline texture to produce the light incidence-enhancing texturing with random pyramids on the front. In this case, an aqueous-alkaline solution mixed with isopropanol was used. In a method step B, the emitter was subsequently 3 produced by phosphorus diffusion in a quartz tube furnace.

As a result, a pn junction between the emitter and the p-doped base region of the silicon wafer thus formed.

The silicate glass resulting from the emitter diffusion was subsequently removed by means of an etching step in a silicate glass etching.

In order to reduce the reflection and the surface recombination speed on the front side, the front side was then provided with a silicon nitride layer.

In a method step C, the application of the metallic contacting structure took place 1 on the front side. In a subsequent temperature treatment step, the so-called contact firing, the solar cell was heated to a temperature of 750 ° C to 850 ° C for a period of a few seconds, so that the electrical connection between the contacting structure 1 and emitter 3 trained.

Subsequently, in process step C, the metallic contacting structure 6 applied on the back. For this purpose, an aluminum layer was first applied over the entire surface to the thermal oxide layer 5 evaporated.

Subsequently, locally electrically conductive connections were made between the aluminum layer and the p-doped base region of the silicon wafer. This was carried out with the known laser fired contact (LFC) method, in which a local melting takes place selectively by means of a laser to form the said local electrically conductive connection, such as in FIG DE 100 46 170 A1 described.

It is essential that then in a process step D, a thermal treatment ("annealing") was carried out. Here, the semiconductor structure comprising all components was heated in a continuous furnace to a temperature of about 350 ° C for a period of about 3 to 5 minutes.

The continuous furnace has a lifting cord transport.

The temperature treatment took place in a gas atmosphere which had an oxygen content <500 ppm and a water vapor content> 5%.

At the inlet and outlet of the continuous furnace, gas exchange with the laboratory atmosphere was prevented by nitrogen gas curtains.

With the method according to the invention, there is thus a considerable improvement and simplification of known production processes for known solar cell structures, in which temperature treatment is possible in process step D, in particular without the supply of hydrogen gas, so that in particular lower safety requirements are necessary and the process costs are reduced.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• US 006136728 A [0013]
• DE 10046170 A1 [0033, 0077]
• EP / [0033]
• DE 10059777 B4 [0037]
• US 7618027 [0040]
• US 2009/0301557 A1 [0050]

Cited non-patent literature

• S. Kontermann, A. Grohe, and R. Preu, "Detailed analysis of annealing silver front side contacts on silicon solar cells", Proceedings of the 33rd IEEE Photovoltaic Specialists Conference, San Diego, CA, USA, 2008, pp. 1-5 [0008]
• G. Schubert, J. Horzel and S. Ohl, Proceedings of the 21st European Photovoltaic Solar Energy Conference, Dresden, Germany, 2006, Investigations on the Mechanism Behind the Beneficial Effect of a Gasketing on Solar Cells with Silver Thick Film Contacts , pp. 1460-6 [0009]
• Y. Abe, H. Nagayoshi, T. Kawaba, N. Arai, T. Saitoh, K. Kamisako, "Effect of High Temperature Steam Annealing for SiO 2 Passivation", Solar Energy Materials and Solar Cells 65 (2001), 607-612 [0012]
• Xiewen Wang, Mukesh Khare and TP Ma, "Effects of Water Vapor Anneal on MIS Devices Made of Nitrided Gate Dielectrics", Symposium on VLSI Technology, Digest of Technical Papers, 1996, 226-227 [0013]
• AS Grove, "Physics and Technology of Semiconductor Devices", John Wiley & Sons, Inc., New York, 1967 [0031]
• K. Maex, M. Van Rossum, "Properties of metal silicides", Inspec, London, UK, 1995. [0032]
• S. Kontermann, A. Wolf, D. Reinwand, A. Grohe, D. Biro and R. Preu "Optimizing Annealing Steps for Crystalline Silicon Solar Cells with Screen Printed Front Side Metallization and on Oxide-Passivated Rear Surface with Local Contacts", Progress in Photovoltaics 17, 2009, pp. 554-66 [0035]
• S. Kontermann, A. Wolf, D. Reinwand, A. Grohe, D. Biro and R. Preu "Optimizing Annealing Steps for Crystalline Silicon Solar Cells with Screen Printed Front Side Metallization and on Oxide-Passivated Rear Surface with Local Contacts", Progress in Photovoltaics 17, 2009, pp. 554-66 [0036]
• D. Biro, G. Emanuel, R. Preu, and G. Willeke, High-capacity walking string diffusion furnaces, in PV in Europe - From PV Technology to Energy Solutions, Rome, Italy, 303-6 (2002) [0037]
• G. Agostinelli, P. Choulat, HFW Dekkers, S. De Wolf, and G. Beaucarne, Screen Proofs large area crystalline silicon solar cells to thin substrates, in Proceedings of the 20th European Photovoltaic Solar Energy Conference, Barcelona, Spain, 647- 50 (2005) [0050]
• O. Schultz, A. Mette, M. Hermle and SW Glunz, Thermal Oxidation for Crystalline Silicon Solar Cells Exceeding 19% Efficiency Applying Industrially Feasible Process Technology, Prog. Photovolt: Res. Appl. 2008; 16: 317-324 [0054]
• S. Mack, U. Jäger, A. Wolf, S. Nold, R. Preu and D. Biro, SIMULTANEOUS FRONT EMITTER AND REAR SURFACE PASSIVATION BY THERMAL OXIDATION - TO INDUSTRIALALLY FEASIBLE APPROACH TO A 19% EFFICIENT PERC DEVICE, 25th European Photovoltaic Solar Energy Conference and Exhibition, Valencia, Spain, 2218-2222, 2010 [0054]
• A. Wolf, A. Walczak, S. Mack, EA Wotke, A. Lemke, C. Bertram, U. Belledin, D. Biro, and R. Preu, THE SINTO PROCESS: UTILIZING A SINX ANTIREFLECTION LAYER FOR EMITTER MASKING DURING THERMAL OXIDATION, Proceedings of the 34th IEEE Photovoltaic Specialists Conference, Philadelphia, PA, USA, 534-539, 2009 [0054]

Claims (23)

Method For producing a photovoltaic solar cell, comprising the following method steps: A Providing a semiconductor structure ( 4 ), which semiconductor structure ( 4 ) comprises a silicon layer and is a precursor in the production process of a photovoltaic semiconductor solar cell, B generating at least one pn junction in the semiconductor structure (B) 4 C) applying at least one metallic contacting structure ( 1 . 6 ) at a contacting surface of the semiconductor structure ( 4 ) for electrically contacting the semiconductor structure ( 4 ) and D thermal treatment by applying temperature to at least the semiconductor structure ( 4 ) and the applied contacting structure ( 1 . 6 ) for a period in the range 1 second to 60 minutes at a temperature in the range 200 ° C to 800 ° C, characterized in that in step D, the thermal treatment is carried out in a gas atmosphere containing less than 15% oxygen and more than 1 Has% water vapor. A method according to claim 1, characterized in that in method step D, the oxygen content of the gas atmosphere is less than 5%, preferably less than 500 ppm, in particular less than 100 ppm. Method according to one of the preceding claims, characterized in that in process step D, the gas atmosphere apart from oxygen and water vapor additionally reactive gases in an amount less than 3%, preferably less than 1%, in particular, that the reaction atmosphere apart from oxygen and water vapor additional only inert gas , In particular, at least one of the gases N ₂ , CO ₂ , Ar or other noble gases. Method according to one of the preceding claims, characterized in that in process step D, the gas atmosphere contains at least 5%, preferably at least 10%, in particular more than 20% water vapor. Method according to one of the preceding claims, characterized in that in process step D, the gas atmosphere less than 90%, preferably less than 70%, in particular less than 50% water vapor. Method according to one of the preceding claims, characterized in that in step D, a heating to a temperature in the range 200 ° C to 500 ° C, preferably in the range 250 ° C to 450 ° C. Method according to one of the preceding claims, characterized in that in step D, the heating for a period of time in the range 1 minute to 10 minutes. Method according to one of the preceding claims, characterized in that in step D, the water vapor is generated pyrolytically, by evaporation of ultrapure water, by means of a steamer and / or by passing N ₂ through ultrapure water or by ultrapure water directly in an oven, in which process step D. is carried out, is evaporated. Method according to one of the preceding claims, characterized in that at least method step D is carried out in a continuous furnace, in particular in a continuous furnace with a process chamber having gas curtains in the input and output region, preferably N ₂ gas curtains. Method according to one of the preceding claims, characterized in that method step D is carried out in a process chamber or a process region of a furnace, which chamber or region is rinsed before the temperature and / or prior to introducing the precursor of the photovoltaic solar cell, preferably by means of an inert gas and especially preferably by means of N ₂ . Method according to one of the preceding claims, characterized in that in method step C the front side ( 1 ) and / or back contacting structure ( 6 ) by applying a paste containing metal particles and preferably glass frit takes place. Method according to one of the preceding claims, characterized in that in step C, the metallization is realized by applying metal-containing pastes and subsequent contact sintering, wherein preferably the application of the paste by screen printing, stencil printing, dispensing, inking, aerosol printing, pad printing, web printing or other methods , A method according to claim 12, characterized in that the Kontaksintern at substrate temperatures of 200 ° C to 950 ° C for durations in the range between 1 second and 10 minutes. Method according to one of the preceding claims, characterized in that in method step C, the front-side contacting structure ( 1 ) is produced and / or reinforced by means of chemical deposition, preferably by means of electrodeposition of layer systems containing nickel and / or silver, and / or copper. Method according to one of the preceding claims, characterized in that in method step C the front side ( 1 ) and / or back contacting structure ( 6 ) is produced by vapor deposition and / or sputtering, preferably by applying layer systems and / or alloys of titanium, palladium, silver, chromium, vanadium, nickel, and / or aluminum. Method according to one of the preceding claims, characterized in that prior to method step D, a dielectric layer ( 2 . 5 ) on at least one side of the semiconductor structure ( 4 ), preferably a layer system of silicon oxide, silicon nitride, aluminum oxide, amorphous silicon, silicon carbide, and / or silicon oxynitride. Method according to one of the preceding claims, characterized in that method step D is carried out after the method steps A, B and C, optionally with the interposition of further method steps and / or that two or more of the method steps are combined and carried out at the same time. A method according to at least claim 9, characterized in that the continuous furnace used is a Hubschnurofen. Method according to claim 18, characterized in that the lifting cords of the furnace consist of ceramics (in particular containing aluminum oxide, silicon oxide), glass (or glass fiber), carbon fiber material, metal or plastic (especially for low temperatures) or composite materials. A method according to at least claim 9, characterized in that the continuous furnace used is a roller kiln. A method according to claim 20, characterized in that the rollers of the roller furnace of at least one of the materials ceramic, in particular containing alumina, silica, glass (or glass fiber), carbon fiber material, Sikrabond, metal or plastic and / or consist of composite materials. Method according to one of the preceding claims, characterized in that the solar cell has local contacts, in particular on the back, in particular LFC and / or i-PERC contacts and / or contacts, which were produced from locally applied pastes. Method according to at least claim 16, characterized in that the dielectric layer is applied by means of the SiNTO, FeDiO or TOPAS process sequence.

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