EP3138119A1 - Process for producing differently doped semiconductors - Google Patents

Abstract

The present invention relates to a liquid-phase process for doping a semiconductor substrate, characterized in that a first composition containing at least a first dopant is applied to one or more regions of the surface of the semiconductor substrate, in order to produce one or more regions of the surface of the semiconductor substrate coated with the first composition; a second composition containing at least a second dopant is applied to one or more regions of the surface of the semiconductor substrate, in order to produce one or more regions of the surface of the semiconductor substrate coated with the second composition, wherein the one or more regions that is/are coated with the first composition and the one or more regions that is/are coated with the second composition are different and do not significantly overlap and wherein the first dopant is a dopant of the n type and the second dopant is a dopant of the p type, or vice versa; the regions of the surface of the semiconductor substrate that are coated with the first composition and those that are coated with the second composition are in each case activated completely or partially; optionally, the non-activated regions of the surface of the semiconductor substrate that are coated with the first composition and those that are coated with the second composition are respectively oxidized; and the semiconductor substrate is heated to a temperature at which the dopants diffuse out of the coating into the semiconductor substrate. The invention also relates to the semiconductors that can be obtained by the process and to the use thereof, in particular in the production of solar cells.

Description

 Method for producing differently doped semiconductors

The present invention relates to a method for producing differently doped semiconductors, the semiconductor obtainable by the method and their use.

For various applications, doped semiconductor layers are needed, e.g. in photovoltaics. Photovoltaics is based on the generation of free charge carriers in one

Semiconductor by incident light. The electrical use of these charge carriers (separation of electrons and holes) requires a p-n transition in the semiconductor. Typically, silicon is used as the semiconductor. The silicon wafer used in this case usually has a basic doping, e.g. with boron (p-type), on. Typically, the p-n junction is generated by in-diffusion of phosphorous (n-type dopant) from the gas phase at temperatures around 900 ° C. Both types of semiconductors (p and n) are used to extract the corresponding ones

Contact carrier contacted with metal contacts.

To optimize the p-n transition, it is advantageous to apply among the

Metal contacts to generate a high doping (to reduce the contact resistance), whereas in the area between the contacts a low doping is advantageous in order to reduce the recombination and the free-carrier-absorption. In order to generate highest efficiencies with respect to the energy conversion, it is furthermore advantageous, in addition to a pn junction, also to generate transitions of regions of the same doping type (pp ⁺ or nn ⁺ ) doped to different levels.

Methods for doping semiconductor substrates are already known in the prior art. For example, US 2012/0052618 A1 discloses a method for selectively doping a wafer by using a liquid, dopant-containing silicon precursor compound, which is applied to the wafer, partially into elemental silicon

containing layers is converted and the unconverted areas of the coating are then oxidized. The different rates of diffusion of the converted and oxidized regions can subsequently produce high and low doped regions in the wafer. However, the doping with different dopants (p- and n-type) is not mentioned. It is thus the object of the present invention to provide a method for doping a semiconductor, which makes it possible to produce differently doped regions with respect to the type and concentration of the doping atoms on the semiconductor.

The present object is achieved by the inventive Flussigphasenverfahren for doping a semiconductor substrate, in particular a silicon wafer, in which

 applying a first composition comprising at least one first dopant to one or more areas of the surface of the semiconductor substrate to produce one or more first composition coated areas of the surface of the semiconductor substrate;

 a second composition containing at least one second dopant is applied to one or more regions of the surface of the semiconductor substrate to produce one or more regions (e) coated with the second composition of the surface of the semiconductor substrate, the one or more regions (e) coated with the first composition and the one or more regions coated with the second composition are different and do not overlap or substantially overlap and wherein the first dopant is an n-type dopant and the second dopant is a p-type dopant or vice versa;

 the portions of the surface of the semiconductor substrate coated with the first composition and the second composition are each partially or fully activated;

 optionally those with the first composition and those with the second

 Composition coated non-activated areas of the surface of the semiconductor substrate are each oxidized; and

 the semiconductor substrate is heated to a temperature at which the dopants diffuse from the coating into the semiconductor substrate.

The compositions used in this process are preferably

Precursorzusammensetzungen. A precursor is understood to mean a chemical compound which is essentially soluble in the composition in the composition or a liquid chemical compound of one or more semiconductor atoms which can be converted into the semiconductor material thermally or with electromagnetic radiation. Also when the invention is described below with reference to such

Precursor compositions is described, it is not limited to this embodiment. In the present case, a liquid-phase process is to be understood as meaning a process in which at least one liquid composition (comprising at least one liquid precursor of the semiconductor or dopant material in which other other liquid or solid dopant precursors, semiconductor precursors and optionally other additives are dissolved or dispersed) and / or at least one solvent-containing formulation containing the (even liquid or solid) dopants, optionally semiconductor precursors (and optionally further additives) are applied to the substrate to be doped. In the case of silicon-based semiconductor precursors, these may then subsequently be thermally or with electromagnetic radiation, for example, into a substantially elementary, amorphous, monocrystalline and / or

polycrystalline silicon-containing coating to be converted. present

Dopant precursors are essentially converted into the underlying dopants and incorporated into the resulting silicon-containing coating. The resulting doped semiconductor substrate is thus a

Semiconductor substrate that has been coated with at least one doped semiconductor layer. The substrate itself may (but does not have to) continue to be doped by diffusion of dopant.

For the purposes of the present invention, an "activation" is to be understood as meaning a "conversion" of the coating from a precursor composition into said elemental, amorphous, monocrystalline and / or polycrystalline silicon-containing coating. "Partial activation" here means that not the entire Coating is converted, but only selected sub-areas

For example, mean that not less than 2% and not more than 98% of the area, preferably not less than 5% and not more than 50% of the area are converted in this way. In various embodiments of the invention but the entire

Coating, i. 100% of the area, activated.

The p-type or n-type dopants can be used in particular in the form of

Element compounds of III. or V. main group. The at least one n-type dopant may preferably consist of phosphorus-containing dopants, in particular PH ₃ , P ₄ , P (SiMe ₃ ) ₃ , PhP (SiMe ₃ ) ₂ , CI ₂ P (SiMe ₃ ), PPh ₃ , PMePh ₂ and P (t-Bu) ₃ , arsenic-containing dopants, in particular As (SiMe ₃ ) ₃ , PhAs (SiMe ₃ ) ₂ , CI ₂ As (SiMe ₃ ), AsPh ₃ , AsMePh ₂ , As (t-Bu) ₃ and AsH ₃ , antimony-containing dopants, especially Sb (SiMe ₃ ) ₃ , PhSb (SiMe ₃ ) ₂ , CI ₂ Sb (SiMe ₃ ), SbPh ₃ , SbMePh ₂ and Sb (t-Bu) ₃ , and mixtures of the foregoing. The at least one p-type dopant may preferably be selected from boron-containing dopants, in particular B ₂ H ₆ , BH ₃ ^* THF, BEt ₃ , BMe ₃ , B (SiMe ₃ ) ₃ , PhB (SiMe ₃ ) ₂ , CI ₂ B (SiMe ₃ ), BPh ₃ , BMePh ₂ , and B (t-Bu) ₃ , and mixtures thereof.

"At least one" as used herein means 1 or more, ie 1, 2, 3, 4, 5, 6, 7, 8, 9 or more. With respect to an ingredient, the indication refers to the kind of the ingredient and not to the absolute number of molecules. "At least one dopant" thus means, for example, at least one type of dopant, ie that one type of dopant or a mixture of several different dopants can be used. The term, together with amounts, refers to all compounds of the type indicated which are included in the composition / mixture, i. that the composition does not contain any further compounds of this type beyond the stated amount of the corresponding compounds.

All percentages associated with those described herein

Compositions are, unless explicitly stated otherwise, by weight, in each case based on the corresponding composition.

"Approximately" or "ca." As used herein in connection with a numerical value refers to the numerical value ± 10%, preferably ± 5%.

The activated coatings which can be prepared by the process according to the invention can contain or consist of elemental silicon, for example in amorphous, monocrystalline and / or polycrystalline form, in combination with the respective dopant.

Likewise, the activated coatings produced by the process according to the invention may be coatings which, in addition to elemental silicon and the respective dopant, also contain other elements. Similarly, the oxidized coatings which can be prepared by the process according to the invention can be silicon oxide contain or consist of in combination with the respective dopant. Also in these coatings optionally other elements may be included.

In the processes according to the invention, the coatings can be treated with the first

In this context, a "structured" coating is to be understood as meaning a coating which does not completely or substantially completely cover the substrate but which partially covers the substrate to form a structuring Typical examples of structured layers are printed conductors (eg for contacts), finger structures or point-like structures (eg for emitter and base regions in back-contact solar cells) and selective emitter structures in solar cells.

In the methods of the invention, the first composition containing at least one first dopant and the second composition containing at least one second dopant are applied to different, non-or substantially non-overlapping regions of the invention

"Substantially overlapping" means that the areas do not overlap with each other by more than 5% of their respective area, it is preferred that the areas do not overlap at all, but it may be process-related

Overlaps come. However, these are often undesirable. The application can be structured in each case, so that the first composition and the second

Composition, for example, one-sided in an interlocking structure

(Interdigitated) are applied to the surface of the silicon wafer or the first composition and the second composition are applied to the respective opposite sides of the silicon wafer.

In various embodiments, prior to the step of heating the silicon wafer (outdiffusion step) (but either before or after, but especially after the activation step, and optionally after the oxidation step), a third composition containing no dopant may be applied to the first and / or second composition

coated activated and / or non-activated areas are applied. This means that the coating of the first or the second composition with a

Coating consisting of the third composition, be coated. These Composition, except for the absence of the dopant, may be identical to the first and / or second composition in terms of ingredients.

This coating with the third composition prevents contamination of the diffusion furnace commonly used in this step in the outdiffusion step, i. an escape of the doping atoms in the furnace atmosphere.

Among the compositions according to the present invention, i. the first and second composition and the optional third composition, in particular SATP conditions (25 ° C, 1, 013 bar) to understand liquid compositions containing either at least one liquid in the case of SATP conditions-containing precursor or at least one solvent and contain or consist of at least one liquid or solid silicon-containing precursor in SATP conditions, in each case in combination with the respective dopant. Particularly good results can be with

Compositions comprising at least one solvent and at least one liquid or solid in SATP conditions containing silicon-containing precursor can be achieved in combination with the respective dopant, since they can be particularly good print.

The precursors generally include all suitable polysilanes, polysilazanes and polysiloxanes. Preferred silicon-containing precursors are (in the case of SATP conditions in particular liquid or solid) silicon-containing compounds of the formula Si _n X _c with X =H, F, Cl, Br, I, C 1 -C 10 -alkyl-, C 1 -C 4 -alkyl Alkenyl, C ₅ -C ₂ o-aryl, n> 4 and 2n <c <2n + 2. Also preferred

Silicon-containing precursors are polysiloxanes, in particular those of the formula Si _n H _c O _d R _e with R = d-Cio-alkyl, C Ci ₀ -alkenyl, C ₅ -C ₂ o-aryl, n> 2 and (n-1 ) <d <n, 0 <c <3n and 0 <e <3n. Also preferred silicon-containing precursors are polysilazanes of the formula Si _n H _m N _b R _c where R = organic radical (preferably R = C 1 -C 10 -alkyl-, C 1 -C 10 -alkenyl, C ₅ -C 20 -aryl, = C 1 -C 10) Alkoxy), n> 2, 0 <m <3n, (n-1) <b <n and 0 <c <3n. Also preferred silicon-containing

Precursors are silicon-containing nanoparticles. The precursors can be used both individually and in mixture. Particular preference is given to using polysilanes. These can also be used individually or in mixture.

Particularly good results can be obtained if a composition is used which has at least two precursors, at least one of which is a hydridosilane, in particular the generic formula Si _n H ₂ n + 2 with n = 3 to 10, and at least one is a hydridosilane oligomer. Corresponding formulations are particularly suitable for the production of high-quality, thin and fine layers from the liquid phase, wet well in the coating process common substrates and have sharp edges after the

Structuring on. Preferably, the formulation is liquid, since it is so easy to handle.

Hydridosilanes of the formula Si _n H _2n + 2 where n = 3 to 10 are non-cyclic hydridosilanes. The isomers of these compounds can be linear or branched. Preferred non-cyclic hydridosilanes are trisilane, iso-tetrasilane, n-pentasilane, 2-silyl-tetrasilane and neopentasilane and octasilane (ie n-octasilane, 2-silyl-heptasilane, 3-silyl-heptasilane, 4-silyl-heptasilane, 2 , 2-disilyl-hexasilane, 2,3-disilyl-hexasilane, 2,4-disilyl-hexasilane, 2,5-disilyl-hexasilane, 3,4-disilyl-hexasilane, 2,2,3-trisil-pentasilane, 2 , 3,4-trisilyl-pentasilane, 2,3,3-trisilyl-pentasilane, 2,2,4-trisilapentasilane, 2,2,3,3-tetrasilyl-tetrasilane, 3-disilyl-hexasilane, 2-silyl 3-disilyl-pentasilane and 3-silyl-3-disilyl-pentasilane) and nonasilane (ie n-nonasilane, 2-silyl-octasilane, 3-silyl-octasilane, 4-silyl-octasilane, 2,2-disilyl-heptasilane , 2,3-disilyl-heptasilane, 2,4-disilyl-heptasilane, 2,5-disilyl-heptasilane, 2,6-disilyl-heptasilane, 3,3-disilyl-heptasilane, 3,4-disilyl-heptasilane, 3 , 5-Disilyl-heptasilane, 4,4-disilyl-heptasilane, 3-disilyl-heptasilane, 4-disilyl-heptasilane, 2,2,3-trisilyl-hexasilane, 2,2,4-trisilyl-hexasilane, 2,2 , 5-trisilyl-hexasilane, 2,3,3-trisily 1-hexasilane, 2,3,4-trisilyl-hexasilane, 2,3,5-trisilyl-hexasilane, 3,3,4-trisilyl-hexasilane, 3,3,5-trisilyl-hexasilane, 3-disilyl-2 Silyl-hexasilane, 4-disilyl-2-silyl-hexasilane, 3-disilyl-3-silyl-hexasilane, 4-disilyl-3-silyl-hexasilane, 2,2,3,3-tetrasilyl-pentasilane, 2,2, 3,4-tetrasilyl-pentasilane, 2,2,4,4-tetrasilyl-pentasilane, 2,3,3,4-tetrasilyl-pentasilane, 3-disilyl-2,2-disilyl-pentasilane, 3-disilyl-2, 3-disilyl-pentasilane, 3-disilyl-2,4-disilyl-pentasilane and 3,3-disilyl-pentasilane), whose formulations give particularly good results.

Also preferably, the hydridosilane of said generic formula is a branched hydridosilane, which leads to more stable solutions and better layers than a linear hydridosilane.

Very particular preference is given to the hydridosilane isotetrasilane, 2-silyltetra-silane, neopentasilane or a mixture of nonasilane isomers which can be prepared by thermal treatment of neopentasilane or by a method described by Holthausen et al. described rule (Poster presentation: A. Nadj, 6th European Silicon Days, 2012). With appropriate

Formulations can get the best results.

The hydridosilane oligomer is the oligomer of a hydridosilane compound, and preferably the oligomer of a hydridosilane. The formulation of the invention is particularly well suited for the production of thin layers, if the

Hydridosilane oligomer has a weight average molecular weight of 200 to 10,000 g / ml. Methods for their preparation are known in the art. Appropriate

Molecular weights can be determined by gel permeation chromatography using a linear polystyrene column with cyclooctane as eluent against polybutadiene as reference.

The hydridosilane oligomer is preferably obtained by oligomerization of non-cyclic hydridosilanes. Unlike hydridosilane oligomers of cyclic hydridosilanes, these oligomers exhibit dissociative dissociation due to the different nature of the reaction

 Polymerization mechanism on a high cross-linking ratio on. Oligomers of cyclic hydridosilanes have instead, if at all, only a very small amount due to the ring-opening reaction mechanism to which cyclic hydridosilanes are subjected

Crosslinking component. Corresponding oligomers prepared from non-cyclic hydridosilanes, unlike oligomers of cyclic hydridosilanes, in solution wet the

Substrate surface well, can be used particularly well for the production of thin layers and lead to homogeneous and smooth surfaces. Even better results are shown by oligomers of noncyclic, branched hydridosilanes. A particularly preferred hydridosilane oligomer is an oligomer obtainable by thermal reaction of a composition comprising at least one non-cyclic hydridosilane having a maximum of 20 silicon atoms in the absence of a catalyst at temperatures of <235 ° C. Corresponding hydridosilane oligomers and their preparation are described in WO

201 1/104147 A1, to which reference is made for the compounds and their preparation and which is incorporated herein by reference in its entirety. This oligomer has even better properties than the other hydridosilane oligomers of non-cyclic, branched hydridosilanes. The Hydridosilan- oligomer may have other radicals in addition to hydrogen and silicon. So can Advantages of the layers made with the formulations result when the oligomer is carbonaceous. Corresponding carbon-containing hydridosilane oligomers can be prepared by co-oligomerizing hydridosilanes with hydrocarbons. Preferably, however, the hydridosilane oligomer is an exclusively hydrogen- and silicon-containing compound which therefore has no halogen or alkyl radicals.

Also preferred are hydridosilane oligomers that are already doped. The hydridosilane oligomers are preferably boron- or phosphorus-doped. Corresponding hydridosilane oligomers can be produced by adding the corresponding dopants already during their preparation. Alternatively, non-doped hydridosilane oligomers already prepared may be p-doped with the above-mentioned p-type or n-type dopants or n-doped by an energetic process (e.g., UV irradiation or thermal treatment).

The proportion of the hydridosilane (s) is preferably from 0.1 to 99% by weight, more preferably from 1 to 50% by weight, very preferably from 1 to 30% by weight, based on the total weight of the particular composition.

The proportion of the or the hydridosilane oligomers is preferably 0.1 to 99 wt .-%, more preferably 1 to 50 wt .-%, most preferably 1 to 20 wt .-% based on the total mass of the respective composition.

The proportion of the hydridosilane oligomer in the particular composition is furthermore preferably 40 to 99.9% by weight, particularly preferably 60 to 99, very particularly preferably 70 to 90% by weight, based on the total mass, in order to achieve particularly good results present hydridosilane and hydridosilane oligomer.

The compositions used in the process according to the invention need not contain a solvent. However, they preferably have at least one solvent. If they contain a solvent, the proportion thereof is preferably 0.1 to 99% by weight, more preferably 25 to 95% by weight, very preferably 60 to 95% by weight, based on the total weight of the particular formulation. Very particular preference is given to compositions comprising 1-30% by weight of hydridosilane, 1-20% by weight of hydridosilane oligomer and 60-95% by weight of solvent, based on

Total mass of the formulation. Solvents which may preferably be used for the compositions described herein are those selected from the group consisting of linear, branched or cyclic saturated, unsaturated or aromatic hydrocarbons having 1 to 12 carbon atoms (optionally partially or completely halogenated), alcohols, ethers, carboxylic acids, Esters, nitriles, amines, amides, sulfoxides and water. Particular preference is given to n-pentane, n-hexane, n-heptane, n-octane, n-decane, dodecane, cyclohexane, cyclooctane, cyclodecane, dicyclopentane, benzene, toluene,

m-xylene, p-xylene, mesitylene, indane, indene, tetrahydronaphthalene, decahydronaphthalene,

Diethyl ether, dipropyl ether, ethylene glycol dimethyl ether, ethylene glycol diethyl ether,

Ethylene glycol methyl ethyl ether, diethylene glycol dimethyl ether, diethylene glycol diethyl ether, diethylene glycol methyl ethyl ether, tetrahydrofuran, p-dioxane, acetonitrile, dimethylformamide, dimethyl sulfoxide, dichloromethane and chloroform.

In addition to the at least one dopant, the at least one hydridosilane and the at least one

Hydridosilane oligomer and the optionally present solvents or other substances, in particular nanoparticles or additives to adjust the rheological properties. Corresponding substances are known to the person skilled in the art. However, it is preferred that the compositions used do not consist of nanoparticles. For the method according to the invention, the semiconductor substrate used is in particular silicon

Used wafers. These may, for example, be polycrystalline or monocrystalline and possibly already ground-doped. This base doping may be a doping with an n- or p-type dopant, as already defined above. The application of the compositions is preferably carried out by a liquid phase method selected from printing processes (in particular flexographic / gravure printing, nanoimaging or microimprinting, inkjet printing, offset printing, reverse offset printing, digital offset printing and screen printing) and spraying processes (pneumatic Spraying, ultrasonic spraying, electrospray method). In general, all known application methods are suitable which enable a structured coating with two different compositions without substantial overlap.

The application of the compositions can, in principle, be carried out flat (that is to say unstructured) or structured. An areal plot may be made, in particular, in cases where the first and second compositions are applied to different sides of the wafer. Particularly fine structures can with the invention

Method are achieved, even if the application of the compositions is already structured on the substrate. A corresponding structured application can e.g. be realized by the use of printing processes. It is also possible structuring via surface pretreatment of the substrate, in particular via a modification of the

Surface tension between substrate and the precursor-containing

Coating composition by a local plasma or corona treatment and thus a local removal of chemical bonds to the substrate surface or a local activation of the surface (eg Si-H termination), by chemical etching or applying chemical compounds (in particular by self-assembled monolayers ). In this way, structuring is achieved in particular by virtue of the fact that the precursor-containing coating composition is more favorable only at the predefined regions

Surface tension adheres and / or that the dried or converted layer adheres only to predefined areas with favorable surface tension.

However, the process according to the invention can preferably be carried out by printing processes.

The method according to the invention is particularly preferably carried out in such a way that the first and the second composition are applied simultaneously or successively without overlapping to different areas of the wafer, the resulting ones

Coatings partially or completely activated and optionally not activated

Coating areas are oxidized on the wafer. Hereby, particularly fine structures with different properties can be produced. With a corresponding method, particularly good and simply structured layers can be produced. After application of the formulations (compositions), it is possible to carry out a pre-crosslinking via UV irradiation of the liquid film on the substrate, after which the still liquid film has crosslinked precursor portions. After application and optionally pre-crosslinking of the formulation, the coated substrate can furthermore preferably be dried before the conversion in order to remove any solvent present. Corresponding measures and conditions for this are known to the person skilled in the art. In order to remove only volatile constituents, in the case of thermal drying, the heating temperature should be less than 200 ° C. Subsequent to the application to the substrate and any subsequent pre-crosslinking and / or drying, the coating composition located on the substrate is fully or partially activated.

A partial activation can be done for example by using a mask or by using contact stamps.

The activation of the method according to the invention can in principle be carried out differently. Preferably, the activation or conversion is carried out thermally and / or using electromagnetic radiation and / or by electron or ion bombardment. Thermal activation is preferably carried out at temperatures of 200-1000 ° C., preferably 250-750 ° C., particularly preferably 300-700 ° C. thermal

Activation times are preferably between 0.01 ms and 360 min. The activation time is more preferably between 0.1 ms and 10 minutes, more preferably between 1 s and 120 s.

Corresponding rapid energetic process guides can be, for example, by the use of an IR radiator, a hot plate, a Heizstempels, a furnace, a flash lamp, a plasma (in particular a hydrogen plasma) or a corona with a suitable gas composition, an RTP system, a microwave system or a

Electron beam treatment (if necessary, in the preheated or warmed up state) done. Alternatively or additionally, activation can be effected by irradiation with electromagnetic radiation, in particular with UV light. The activation time may be preferably between 1 s and 360 min. The structuring or (partial) activation can be realized in this case, for example by using point or line-shaped radiation sources or by the use of masks. The activation is particularly preferably carried out by irradiation with laser radiation. The use of point or line-shaped radiation sources, in particular of lasers, is advantageous, since hereby particularly fine

Structures can be achieved. In addition, when monochromatic radiation is used, the parasitic absorption can be reduced by selective adjustment of the wavelength required for the activation and thus the unwanted heating of substrate and / or surroundings can be prevented. The use of electromagnetic radiation for activation is thus preferred because of this.

Also possible is activation under ion bombardment. The ions can be generated in different ways. Often come impact ionization, in particular

Electron impact ionization (El) or chemical ionization (Cl), photoionization (PI),

Field Ionization (Fl), Fast Atomic Bombardment (FAB), Matrix Assisted Lasers

Desorption / Ionization (MALDI) and electrospray ionization (ESI) are used. A

Structuring can also be achieved via masks in the case of ion bombardment.

Partial activation thus results in areas on the substrate where the coating composition thereon has been converted and areas where the coating composition thereon has not been converted. In the present case, an activation can be understood to mean a conversion of the deposited precursors of the resulting coating film into amorphous or crystalline semiconductor layers. In the case of using exclusively silicon-containing precursors, the activation is preferably carried out in such a way that, after the conversion, structured amorphous or crystalline, in particular polycrystalline or monocrystalline, silicon layers result. Means and ways for this are known in the art. In one embodiment, the activation is performed such that amorphous silicon (a-Si) is formed. If not dried before conversion, unconverted areas can be dried after conversion. The drying is also carried out here at temperatures below 200 ° C, preferably in the range of 100 to 200 ° C. By means of the drying, defined states can also be set in the regions with unconverted coating, with which the optical and electrical properties of the coating can be controlled after the subsequent optional oxidation step.

After the partial conversion, unconverted coating on the substrate can be oxidized. When using silicon precursor compounds, silicon oxide-containing layer structures thus arise in the regions with unconverted coating. The converted silicon-containing regions already obtained by the previous conversion are not oxidized, so that silicon-containing layer structures which directly adjoin silicon oxide-containing layer structures can be obtained by the process according to the invention. Due to the use of differently doped starting compositions, n-doped silicon-containing, n-doped silicon oxide-containing, p-doped silicon-containing and p-doped silicon oxide-containing layer structures are thus obtained. The silicon-containing and silicon oxide-containing layer structures differ in their diffusion rates, so that in the diffusion step, the doping atoms diffuse from the silicon-containing layers with a higher diffusion rate into the underlying substrate than the doping atoms from the silicon oxide-containing layers. Therefore, highly doped regions are created under the activated regions, while low-doped regions are created under the non-activated, oxidized regions.

The person skilled in the art knows how to choose the oxidation conditions so that unconverted coating regions can be oxidized without oxidizing already converted regions as well.

Preferably, the oxidation takes place in an oxygen-containing atmosphere at a temperature <300 ° C, more preferably at a temperature <150 ° C, particularly preferably at a temperature <100 ° C. Most preferably, the oxidation takes place in one

Oxygen-containing atmosphere at room temperature. The oxygen-containing atmosphere preferably has an oxygen concentration of 1 to 100 mol% and may contain nitrogen or argon as further gaseous constituents, for example. Particular preference is furthermore the oxidation with oxidizing agents selected from the group consisting of ozone, carbon dioxide, hydrogen peroxide (H ₂ 0 ₂ ), water vapor (H ₂ 0), a mono- or polyhydric alcohol, a ketone, a carboxylic acid (especially trichloroacetic acid), a carbonic acid ester and mixtures comprising trichloroacetic acid and oxygen, and HCl and oxygen. Means and ways of oxidation with these

Oxidizing agents are known to the person skilled in the art. Particularly preferred is the use of ozone, carbon dioxide, hydrogen peroxide (H ₂ 0 ₂ ), water vapor (H ₂ 0), a carboxylic acid (especially trichloroacetic acid), a carbonic acid ester and a mixture comprising trichloroacetic acid and oxygen.

The method described for doping silicon wafers can furthermore be carried out several times simultaneously or chronologically in succession with respect to a wafer, although corresponding areas of the wafer surface are coated either several times with the first composition or several times with the second composition but not with both compositions , The activation of different coatings can take place simultaneously or successively. That is, the invention encompasses both

Processes in which the first and second compositions are applied simultaneously or sequentially followed by complete or partial activation followed by optional oxidation of both the first and second composition coated areas, and methods in which only the first composition applied, fully or partially activated and optionally oxidized and then the second composition is applied, fully or partially activated and optionally oxidized.

The diffusion step, i. The step of heating the semiconductor substrate to allow the doping atoms to diffuse out of the coating into the underlying semiconductor substrate takes place in various embodiments at temperatures of more than 700 ° C., in particular 700-1200 ° C. Such a step is carried out, for example, for 10 minutes to 10 hours, in particular at least about 30 minutes.

In other embodiments, activation is performed to form crystalline silicon. It is particularly preferred to carry out the activation so that the Silicon epitaxially crystallized. That is, the deposited doped precursor conforms to the silicon wafer in the crystal structure. Especially when using

monocrystalline Si wafers (FZ or Cz), the epitaxially crystallized region thus has a very high electronic quality and does not have to be subsequently removed. This is advantageous, as this eliminates the additional process step of removing. The epitaxial growth is preferably carried out at temperatures of 600 - 1200 ° C, which prevail for a period of 30 s - 3 hours. In particular, epitaxial growth can also be produced by a rapid thermal annealing step of 20-40 s at temperatures of 800-1200 ° C. Advantageous for the epitaxial growth is the high purity of the polysilanes used and the small thickness of the deposited layers of preferably 5-150 nm.

The diffusion step can be carried out under a protective gas atmosphere, in particular an argon or nitrogen atmosphere, or alternatively also in an oxygen-rich environment. In various embodiments, the diffusion step is carried out in the presence of oxygen. This results in an in situ oxidation of the elemental silicon on the

Substrate surface where an oxide grows up. This can then be referred to as

Passivation layer can be used. This oxidation need not be limited to certain areas of the surface, but can generally occur in all areas in which elemental silicon comes into contact with the oxygen-containing atmosphere. The oxide produced in this way typically has a layer thickness of approximately 10 nm. Alternatively, such an oxidation step may also take place separately after the diffusion step.

The step is usually carried out in a diffusion oven. This furnace may be, for example, a continuous band furnace or a quartz tube furnace.

The methods described herein may further include a step of removing the oxidized areas of the coating of the surface of the silicon wafer. This can be done for example by means of a wet-chemical etching process. To remove silicon oxide, for example, a wet chemical etching method using

Hydrofluoric acid, for example 2-10% HF in water. Such an etching step may be carried out after the outdiffusion step, for example, over a period of 1 to 20 minutes. With such a step, both the oxides that are not in the oxidation of activated areas of the coatings are formed, as well as the possibly produced during the diffusion step oxides are removed.

In various embodiments of the invention, the inventive

Method for the different doping of a silicon wafer for the production of back-contact solar cells, comprising the steps

1 . Printing a liquid, a p-type dopants containing Si-based

 Composition in the form of a wet film in finger structure or punctiform on one side of the silicon wafer;

 2. Printing a liquid, n-type dopant containing Si-based

 Composition in the form of a wet film in the according to 1. deposited form of complementary shape on the same side of the silicon wafer;

 3. conversion of the wet films into elemental silicon, in particular amorphous or

 crystalline, epitaxial silicon, or silicon oxide by complete or partial conversion or oxidation

 4. Outdiffusion

 5. Optional: removal of the SiO, e.g. by means of hydrofluoric acid

In all embodiments of the invention described herein, in which the two

In addition, when the composition is applied to the same side of the wafer, the method may additionally include the step of applying another composition to the

opposite side of the semiconductor substrate, i. in particular of the wafer. This composition may also be liquid, for example in the form of a

Wet film to be printed. This composition may contain either n- or p-type dopants, especially n-type dopants. In various embodiments, the composition is a precursor composition and defined as those above

described first or second composition. The application, activation, oxidation, etc. can also be done as described above for the first and second compositions. In particular, the corresponding activation and optional oxidation steps can be carried out together with the activation / oxidation of the first and / or second oxidation steps

Composition coated areas or done separately. In various other embodiments of the invention, the method according to the invention is directed to the different doping of a silicon wafer for the production of bifacial solar cells, comprising the steps

1 . Printing a liquid, a p-type dopants containing Si-based

 Composition in the form of a wet film on one side of the silicon wafer

 2. Conversion of the wet film into elemental silicon, in particular amorphous or

 crystalline, epitaxial silicon, or silicon oxide by complete or partial conversion or oxidation

 3. Printing a liquid, n-type containing Si-based dopant

 Composition in the form of a wet film on the other side of the silicon wafer

4. Conversion of the wet film into elemental silicon, in particular amorphous or

 crystalline, epitaxial silicon, or silicon oxide by complete or partial conversion or oxidation

 5. outdiffusion

 6. Optional: removal of the SiO, e.g. by means of hydrofluoric acid

The present invention also relates to the semiconductor substrates produced by the process according to the invention and to their use, in particular for the production of electronic or optoelectronic components, preferably solar cells. The solar cells can be, for example, back-contact solar cells.

In the production of solar cells, the semiconductor substrate produced according to the invention can be coated in a further step with a silicon nitride layer (flat, especially over the entire surface), after which a metal-containing composition for the production of metallic contacts, for example a silver paste, on certain areas of

Silicon nitride layer is applied and fired by heating to make contact with the underlying doped layer. The metal-containing composition is applied in particular in the areas that are highly doped.

Finally, the present invention also covers solar cells and solar modules which contain the semiconductor substrates produced according to the invention. The following examples illustrate the subject matter of the present invention without being self-limiting.

Examples

1 . By spin coating were phosphorus-doped formulations consisting of 30% neopentasilane with 1.5% phosphorus doping and 70% solvent toluene and

 Cyclooctane on both sides of an n-type silicon wafer of an impedance of 5 ohmcm deposited. Conversion at 500 ° C for 60 s into a 50 nm thick amorphous one

 Silicon layer. Outdiffusion of the phosphorus atoms at 30 min 1000 ° C in the Si wafer. It forms a phosphorus-doped region in the silicon wafer with a

Sheet resistance of 60 ohms / sq. The emitter saturation current of the heavily doped region could be determined to be 800 fA / cm ² . Furthermore, it has been shown that the amorphous silicon epitaxially crystallizes on the silicon wafer during outdiffusion. Furthermore, it could be shown that the amorphous silicon adapts to the crystal structure of the silicon wafer and epitaxially crystallizes on the silicon wafer during the outdiffusion, as can be seen in the diffraction image attached as Appendix 1.

2. Boron-doped formulations consisting of 30% by spin coating

 Neopentasilane with 1.5% boron doping and 70% solvent toluene and cyclooctane deposited on both sides of an n-type silicon wafer of an ohmic resistance of 5 ohmcm. Conversion at 500 ° C for 60 s into a 50 nm thick amorphous silicon layer.

Outdiffusion of the boron atoms at 60 min 1050 ° C in the Si wafer. A boron-doped region forms in the silicon wafer with a sheet resistance of 50 ohms / sq. The emitter saturation current of the heavily doped region could be determined to be 1000 fA / cm ² . Furthermore, it has been shown that the amorphous silicon epitaxially crystallizes on the silicon wafer during outdiffusion.

3. Production of a Bifacial Solar Cell: By spin-coating were boron-doped

Formulations consisting of 30% neopentasilane with 1.5% boron doping and 70% solvent toluene and cyclooctane on the front of an n-type silicon wafer of an impedance of 5 ohmcm deposited. Conversion at 500 ° C for 60 s into a 50 nm thick amorphous silicon layer. Subsequently, by spin-coating deposition of a phosphorus-doped formulations consisting of 30% neopentasilane with 1.5% phosphorus doping and 70% solvent toluene and cyclooctane on the back of the n- Type wafers. Conversion at 500 ° C for 60 s into a 50 nm thick amorphous silicon layer. Outdiffusion of boron and phosphorus atoms at 1050 ° C for 30 min into the Si wafer. Subsequently, deposition of aluminum in a finger structure on the front and the entire surface on the back. The solar cell produced in this way had an efficiency of 10.2%. Production of a back-contact solar cell a. Printing a liquid, a p-type dopant containing, Si-based composition in the form of a wet film in finger structure or punctiform on one side of the silicon wafer. Ink usually contains 30%

 Neopentasilane with 1 - 10% boron doping and 70% solvent toluene and cyclooctane. The fingers typically have widths of 200 μηη - 1000 μηη .; The points have a diameter of 10 μηη - 400 μηη.

 b. Printing a liquid, n-type dopant containing, Si-based composition in the form of a wet film in to 1 according to. Deposited structure of complementary shape on the same side of the silicon wafer. Ink also normally contains 30% neopentasilane with 1 - 10% phosphorus doping and 70% solvent toluene and cyclooctane. The fingers typically have widths of 200 μηη - 1000 μηη .;

 c. Conversion of the wet films into elemental silicon, in particular amorphous silicon, or silicon oxide by partial conversion or oxidation. The

 Conversion takes place at temperatures of 400 - 600 ° C. Duration 1 s - 2 minutes. Preferably 60 s at 500 ° C. Oxidation in an oxygen-containing atmosphere at a temperature between room temperature and 300 ° C. Duration: Depending on temperature 30 s - 30 min. The layer thickness of the amorphous silicon is 10-100 nm.

 d. Printing a liquid, p- or n-type dopant-containing Si-based composition in the form of a wet film on the opposite side of the wafer;

e. Conversion of the wet films into elemental silicon, in particular amorphous silicon, or silicon oxide by partial conversion or oxidation f. Discharge at 700 - 1300 ° C for a period of 5 - 120 minutes under a nitrogen atmosphere. Optional addition of oxygen in the form of O ₂ or H ₂ O. By adding the oxygen, the Si surface oxidizes and a SiO film grows on the Si wafer. Typical Schich thickness of SiO is 10 nm, g. Optional: Removal of the SiO, eg by means of hydrofluoric acid, for 1 to 15 minutes in 1 to 40% H at room temperature.

Claims

claims

1 . Liquid phase method for doping a semiconductor substrate, characterized in that

 a first composition containing at least one first dopant is applied to one or more regions of the surface of the semiconductor substrate to produce one or more regions (e) of the surface of the semiconductor substrate coated with the first composition;

 a second composition comprising at least one second dopant is applied to one or more regions of the surface of the semiconductor substrate to produce one or more regions (e) coated with the second composition of the surface of the semiconductor substrate, wherein the one or more Area (s) coated with the first composition and the one or more areas coated with the second composition are different and do not substantially overlap, and wherein the first dopant is a

N-type dopant and the second dopant is a p-type dopant or vice versa;

 - those with the first composition and those with the second composition

 coated areas of the surface of the semiconductor substrate are respectively fully or partially activated;

 - Optionally with the first composition and with the second

 Composition coated non-activated areas of the surface of the semiconductor substrate are each oxidized; and

 - The semiconductor substrate is heated to a temperature at which the dopants diffuse from the coating in the semiconductor substrate.

2. A method according to claim 1, characterized in that the step of fully or partially activating and / or oxidizing the areas coated with the first composition prior to the applying step and the step of

full or partial activation and oxidation of the second composition takes place. A method according to claim 1 or 2, characterized in that prior to the step of heating the semiconductor substrate, a third composition containing no dopant is applied to the activated and / or non-activated areas coated with the first and / or second composition.

Method according to one of claims 1 to 3, characterized in that the first composition and / or the second composition and / or optionally the third composition is applied by means of a printing or spraying on the semiconductor substrate.

Method according to one of claims 1 to 4, characterized in that

 (a) the at least one n-type dopant is selected

a. phosphorus-containing dopants, preferably PH ₃ , P ₄ , P (SiMe ₃ ) ₃ , PhP (SiMe ₃ ) ₂ ,

CI ₂ P (SiMe ₃ ), PPh ₃ , PMePh ₂ and P (t-Bu) ₃ ,

b. Arsenic-containing dopants, preferably As (SiMe ₃ ) ₃ , PhAs (SiMe ₃ ) ₂ , Cl ₂ As (SiMe ₃ ), AsPh ₃ , AsMePh ₂ , As (t-Bu) ₃ and AsH ₃ ,

c. antimony-containing dopants, preferably Sb (SiMe ₃ ) ₃ , PhSb (SiMe ₃ ) ₂ , Cl ₂ Sb (SiMe ₃ ), SbPh ₃ , SbMePh ₂ and Sb (t-Bu) ₃ ,

and mixtures of the foregoing; and or

 (b) the at least one p-type dopant is selected

a. boron-containing dopants, preferably B ₂ H ₆ , BH ₃ ^* THF, BEt ₃ , BMe ₃ , B (SiMe ₃ ) ₃ ,

PhB (SiMe ₃ ) ₂ , CI ₂ B (SiMe ₃ ), BPh ₃ , BMePh ₂ , B (t-Bu) ₃ ,

and mixtures thereof.

Method according to one of claims 1 to 5, characterized in that the first and / or second and / or optional third composition a

Precursor composition is, the

 (a) at least one silicon-containing precursor liquid under SATP conditions; or

(B) at least one solvent and at least one liquid or solid under SATP conditions, silicon and / or germanium-containing precursor comprises.

A method according to claim 6, characterized in that the precursor is selected from a. Polysilanes of the generic formula Si _n X _c with X = H, F, Cl, Br, I, Ci-Ci ₀ alkyl, d-Cio-alkenyl, C ₅ -C 2o-aryl, n> 4 and 2n <c < 2n + 2

b. Polysiloxanes of the generic formula Si _n H _c OdR _e with R = Ci-Ci ₀ alkyl, Ci-Ci ₀ alkenyl, C ₅ -C2o-aryl, n> 2 and (n-1) <d <n, 0 <c <3n and 0 <e <3n and

c. Polysilazanes of the formula Si _n H _m N _b R _c where R is _{C 1} -C 10 -alkyl-, C 1 -C 10 -alkenyl, C ₅ -C 20 -aryl,

= Ci-Cio-alkoxy, n> 2, 0 <m <3n, (n-1) <b <n and 0 <c <3n.

8. The method according to claim 6 or 7, characterized in that the precursor a

 Silicon-containing nanoparticle is.

9. The method according to any one of claims 6 to 8, characterized in that the

 Precursor composition has at least two precursors, of which

 at least one hydridosilane oligomer and at least one, optionally

branched, hydridosilane of the generic formula Si _n H ₂ n ₊ 2 with n = 3 to 10,

 in particular selected from iso-tetrasilane, 2-silyl-tetrasilane, neopentasilane or a

Mixture of nonasilane isomers.

10. The method according to claim 9, characterized in that the hydridosilane oligomer (a) has a weight-average molecular weight of 200 to 10,000 g / mol; and / or (b) was obtained by oligomerization of non-cyclic hydridosilanes; and or

(C) is obtainable by thermal reaction of a composition comprising at least one non-cyclic hydridosilane having a maximum of 20 silicon atoms in the absence of a catalyst at temperatures of less than 235 ° C. 1 1. Method according to one of claims 1 to 10, characterized in that the non-activated areas of the coating are converted into doped silicon oxide by the oxidation.

12. The method according to any one of claims 1 to 1 1, characterized in that the

 Activation thermally using electromagnetic radiation and / or

 Electron or ion bombardment and / or by means of heat conduction and / or by means of

Heat radiation takes place. Method according to one of claims 1 to 12, characterized in that

 (a) the oxidation takes place in an oxygen-containing atmosphere at a temperature <300 ° C; and or

(B) the oxidation with an oxidizing agent selected from the group consisting of ozone, carbon dioxide, hydrogen peroxide (H ₂ 0 ₂ ), water vapor (H ₂ 0), a mono- or polyhydric alcohol, a ketone, a carboxylic acid, a carbonic acid ester and mixtures comprising trichloroacetic acid and oxygen, and HCl and

 Oxygen is carried out.

Method according to one of claims 1 to 13, characterized in that the diffusion step at temperatures of more than 700 ° C, in particular 700 - 1 100 ° 10 minutes to 1 h, in particular 30 minutes, is performed.

Method according to one of claims 1 to 14, characterized in that the coating is converted into crystalline, in particular epitaxially crystallized silicon by the activation.

Method according to one of claims 1 to 15, characterized in that after or during the diffusion step, an oxidation step in an oxygen-containing

Atmosphere is performed in which elemental silicon on the surface of the semiconductor substrate to silicon oxide, in particular with a layer thickness of 10 nm, is oxidized.

Method according to one of claims 1 to 16, characterized in that the semiconductor substrate is a silicon wafer, in particular a silicon wafer having one or a p-type base doping.

Method according to one of claims 1 to 17, characterized in that the first composition and the second composition on the same side of the

Semiconductor substrate are applied, in particular in an interlocking structure.

19. The method according to claim 18, characterized in that prior to the activation step, a further composition comprising at least one n- or p-type dopant, in particular n-type, applied to the opposite side of the semiconductor substrate and also fully or partially activated and optional is oxidized.

20. The method according to any one of claims 1 to 19, characterized in that the first composition and the second composition are applied to the respective opposite sides of the semiconductor substrate. 21. Method according to one of claims 1 to 20, characterized in that after the step of the outdiffusion, the oxidized areas of the coating and the surface of the semiconductor substrate are removed, in particular by means of a wet chemical

 Etching method. 22. Semiconductor substrate, in particular silicon wafer, produced by a method according to one of claims 1 to 21.

23. Use of the semiconductor substrate according to claim 22 for the production of solar cells. 24. Solar cell or solar module containing the semiconductor substrate according to claim 23.