EP2203248A1

EP2203248A1 - Method and device for producing silicon

Info

Publication number: EP2203248A1
Application number: EP08840408A
Authority: EP
Inventors: Jan-Philipp Mai
Original assignee: Individual
Current assignee: Individual
Priority date: 2007-10-17
Filing date: 2008-10-17
Publication date: 2010-07-07
Also published as: CA2703040A1; JP5383688B2; US20100284887A1; DE102007050010A1; WO2009050264A1; JP2011500495A

Abstract

The present invention relates to a method for producing pure silicon from, for example, optionally doped quartz sand, by thermal reduction in a microwave oven.

Description

Method and apparatus for producing silicon

The present invention relates to a method for producing silicon, in particular high-purity silicon, as required for the production of semiconductors and solar cells, and a device therefor.

For the application in these areas silicon is required, whose degree of contamination is extremely low or precisely controlled. In addition, the manufacturing process should be inexpensive.

Various methods for the production of ultrapure silicon are known.

According to one approach, metallurgical silicon is used as starting material, which is obtained from quartz sand in a blast furnace process. The metallurgical silicon is then converted to polycrystalline ultrapure silicon via a multistage trichlorosilane-based process. Here, the metallurgical silicon is reacted with silicon tetrachloride and hydrogen to trichlorosilane and recovered from the trichlorosilane by disproportionation of silane tetrachloride and silane. From the silane formed is then obtained by thermal decomposition of silicon rods ultrapure silicon.

According to another approach, silicon is made of quartz or quartz glass

Received reduction.

An example of this is the so-called carbothermic reduction, wherein carbon is used as a reducing agent. Common is the reductive

Method that the starting material for the reaction must be melted, which is an energy-intensive process.

So it is known to perform the melting in an electric arc furnace. From

The disadvantage here is that the electrodes used in an electric arc furnace are subject to wear and also the risk of contamination of the

Electrodes by the reducing agent, such as carbon. There was therefore a need for a method whereby silicon can be conveniently obtained from a readily available raw material in a simple manner and energy.

The inventive method is based on the second approach, which is based on the reductive recovery of silicon.

According to the present invention, there is provided a process for producing silicon by reductively reacting a silica-based raw material with a reducing agent, wherein the silica-based raw material is reacted with the reducing agent in a microwave oven.

The silicon dioxide-based starting material used according to the invention may be quartz sand, quartz or glass.

The glass may be quartz glass, ie a glass of 100% SiO ₂ , or quartz glass, to which suitable doping elements have been added as required. Advantageously, if possible, a starting material is used whose composition corresponds to the requirements of the later application, for example with respect to the type and amount of the doping elements. As a result, the expense of possibly required purification of the resulting silicon can be avoided or at least reduced.

For the process according to the invention, the silica-based starting material is comminuted and used, for example, in powder form. A suitable powdery starting material is, for example, quartz flour.

For the reduction, a reducing agent can be used, as it is known for the production of silicon by thermal reduction. Examples of these are carbon-based reducing agents such as carbon powder, graphite powder or a mixture of carbon powder and graphite powder, or aluminum, magnesium, etc.

According to the invention, the reduction preferably takes place carbothermally, that is to say with carbon-based reducing agents.

Heating in a microwave oven is done by exciting the material to be heated with electromagnetic radiation. For this purpose, the reaction mixture of starting material and reducing agent is placed in a suitable reaction vessel. This reaction container may be made of a material that is transparent to the operating frequency of the microwave oven used.

Alternatively, a container may be used which consists of a material which is not or only partially transparent to the operating frequency of the microwave oven used. In this case, the container is also heated, so that the heating and the melting by heat conduction from the container material is supported in the mixture to be reacted.

The container material is therefore not critical, as long as it is transparent to the microwaves or by heat conduction allows the necessary heating of the mixture to be reacted.

Advantageously, microwave ovens can be used for the method according to the invention, which work with a frequency, as used for domestic microwave ovens. These use electromagnetic radiation with a frequency of typically around 2.455 GHz.

Since according to the invention in principle microwave ovens can be used, as they are commercially available at low cost, the inventive method is characterized in particular by a simple apparatus handling. Preference is given to using microwave ovens which have a power control, in particular a continuous power control, so that, for example, the irradiation of the microwaves can be adjusted and regulated as required. The use of power controlled microwave ovens is another contribution to energy saving.

To produce the silicon, the silica-based starting material is ground to a small size and mixed with the reducing agent. The resulting mixture is placed in a container and the silica-based starting material is heated and melted by the action of the microwaves, the reduction being carried out by the reducing agent.

The reaction is preferably carried out under an inert gas atmosphere, for example nitrogen or argon or vacuum, in order to avoid a possible reaction of the silicon formed with atmospheric oxygen.

The direction of irradiation of the electromagnetic radiation can in principle be chosen arbitrarily, as long as sufficient heating of the starting material takes place up to the melt.

The attached figure shows schematically a device for a preferred embodiment according to the invention, the device also forming an object of the invention.

According to the preferred embodiment shown in the figure, the thermal reduction of the starting material may be carried out in connection with a purification according to the principle of the zone melting process.

In this case, a zone of the material body to be cleaned is melted and the melting zone is guided through the material body. The impurities accumulate in the progressing melt front. Zone melting can be performed horizontally or vertically. To carry out the zone melting, the reaction product, which consists essentially of silicon, is melted zone by zone with the aid of microwave irradiation. Silicon itself can not be directly excited by microwaves and thus heated. In this case, since the silicon can not be sufficiently heated directly by the microwave irradiation, a container made of a material which is excited and heated by the frequency of the electromagnetic radiation of the microwave oven used is used. The heating and the melting of the silicon takes place here by conduction of heat from the container wall into the silicon. The container material is therefore to be tuned with regard to the operating frequency of the microwave oven used. Examples of suitable container materials for commercial microwave ovens are graphite, silicon carbide, etc. These materials show when excited with electromagnetic radiation of about 2.455 GHz of commercial microwave ovens a high energy consumption, and thus a corresponding heating of the silicon.

The region of the radiation or heat input and thus the melt front can be vertical, that is perpendicular to the surface of the reaction product obtained, or horizontally, that is parallel to the surface of the resulting reaction product, are performed.

So that the melt front can be guided in the desired direction, means for guiding the radiation front 4 are provided. For example, the corresponding microwave sources or the container 2 or both, the container 2 and the microwave sources, can be designed to be movable. Advantageously, the microwave sources are positioned so that the field maxima of the irradiated microwaves are generated in the regions of the reaction product to be heated.

According to a preferred embodiment, the container 2 is designed to be movable both in the vertical and in the horizontal direction. In the figure, an arrangement for a method according to the invention with a vertical zone melting process is shown by way of example.

To carry out the zone melting, the container 2 with the reaction product is exposed to the side of the electromagnetic radiation.

The direction of movement of the radiation front 4 or the container 2 for the zone melting process is shown schematically by arrows.

If the conversion into silicon is combined with a zone melting process, it has proved to be advantageous to use a separate radiation source 3 for melting the starting material based on silica and reacting it with the reducing agent, which irradiates the starting material from above or else from below.

In accordance with the invention, quartz glass which is appropriately doped, if necessary, is ground, mixed with the likewise finely ground reducing agent and placed in a container.

The container can be placed in a commercial microwave and there by irradiation, the starting material is melted and reacted with the reducing agent to silicon.

According to the invention, depending on the embodiment, a plurality of preferably movably arranged containers can be introduced simultaneously into the microwave oven.

According to a preferred embodiment, the reaction mixture of

Pre-heated starting material and reducing agent prior to thermal reduction.

Preferably is preheated to a temperature in a range of 500 ⁰ C.

The preheating is preferably done within the microwave to avoid possible burning of the reducing agent. By prior heating of the reaction mixture, the energy input required for the thermal reduction can be reduced.

It has also been found that a simultaneous additional heating during and after the reaction promotes the processability of the resulting reaction product. In addition, a better absorption of the microwaves can be observed with simultaneous additional heating.

This means that the microwave power can be reduced. For heating, a heater other than the microwave source may be provided in the microwave oven. For this purpose, a conventional and known heating device may be provided in the microwave oven. Particularly suitable is an induction heater.

To avoid possible contamination, the starting materials and products should be kept under inert gas until they cool to room temperature.

With the method according to the invention can be obtained in a simple manner and energy low on the basis of commercial microwave ovens by reductive conversion of pure silicon.

LIST OF REFERENCE NUMBERS

Microwave oven Container for holding the starting material and reducing agent Radiation source for melting Radiation front for zone melting Movement direction of the vessel and / or the radiation front for zone melting

Claims

claims

A process for producing silicon by thermal reduction of a silica-based raw material with a reducing agent in a microwave oven.

2. The method according to claim 1, characterized in that the starting material is selected based on silica based on quartz, quartz glass and doped silica glass.

3. The method according to claim 1 or 2, characterized in that a reducing agent is used based on carbon.

4. The method according to claim 3, characterized in that as a reducing agent carbon powder, graphite powder or a mixture thereof is used.

5. The method according to any one of the preceding claims, characterized in that the silicon obtained in the microwave oven is additionally subjected to a zone melting process.

6. The method according to any one of the preceding claims, characterized in that the reaction mixture of starting material and reducing agent is preheated before the thermal reduction.

7. The method according to any one of the preceding claims, characterized in that the thermal reduction with simultaneous additional heating of the reaction mixture of starting material and

Reductant is carried out.

8. The method according to any one of the preceding claims, characterized in that the reaction product obtained after the thermal reduction is heated or kept warm.

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

10. A device for producing silicon by thermal reduction of a silica-based starting material with a reducing agent, wherein the device is a microwave oven (1) and is provided for receiving at least one container (2), wherein microwave sources for generating a radiation front (4 ) are provided for performing a zone melting process.

1 1. Apparatus according to claim 10, wherein the at least one container (2) consists of a material which is not transparent to the operating frequency of the microwave source used and is heated by the microwaves.

12. The apparatus of claim 10 or 1 1, wherein means for vertical or horizontal guidance of the radiation front (4) are provided.

13. The apparatus of claim 12, wherein the means are selected from at least one movably arranged microwave source, at least one movably arranged container (2) and a combination thereof for generating a movable radiation front (4).

14. The apparatus of claim 13, wherein the at least one container (2) is movable in the vertical and horizontal directions.

15. Device according to one of claims 10 to 14, wherein an additional heater different from the microwave source is provided.

16. The apparatus of claim 14, wherein the additional heater is an induction heater.

17. Use of a microwave oven for the thermal reduction of a silica-based starting material with a reducing agent to silicon.