DE1215665B - Process for producing high purity silicon carbide - Google Patents

Description

Method for producing high-purity silicon carbide For semiconductor arrangements which are to be used, especially at high temperatures, a semiconductor material is desired whose intrinsic conduction only has a disruptive effect at temperatures above the operating temperature. In addition to silicon, such a material is also silicon carbide. The difficult processing and the insufficient purity of the commercially available qualities, however, have hitherto prevented its use as a semiconductor material. It is known that commercially pure silicon carbide can be sublimated to form single crystals, the so-called ec silicon carbide, at very high temperatures (around 25001 C). In addition, processes are known for producing high-purity silicon carbide by thermal decomposition of a high-purity, gaseous silicon compound together with gaseous hydrocarbons, in which a relatively loose pile of small, pure single crystals is obtained as so-called β-silicon carbide by the joint decomposition of silicon tetrachloride and hydrocarbons in a hydrogen stream. It has also already been possible to produce larger silicon carbide single crystals by thermal decomposition of volatile substances such as CH.SiC1, or of mixtures of e.g. B. Sic14 and a hydrocarbon with hydrogen as a carrier gas.

The invention relates to an improved method for producing high-purity silicon carbide for semiconductor devices by thermal decomposition of a gaseous silicon compound and gaseous hydrocarbons or hydrocarbon derivatives that do not form water during decomposition or reduction, in the presence of a diluent gas, in particular hydrogen, the carbide on a is deposited on supports heated to over 11501 ° C. According to the invention, it is characterized in that the atomic ratio of the silicon contained in the silicon halide to the carbon contained in the hydrocarbon is selected between 5: 1 and 100: 1 .

The main advantage of the process is that with cubic f-silicon carbide, possibly also as a single crystal can be and that silicon carbide monocrystals can also be formed with this method have defined pn junctions made.

The surprising fact arose that if a silicon carbide with a stoichiometric composition is to be obtained, the ratio of silicon to carbon in the starting materials must be greater than 1. The reason is presumably to be found in the fact that at the temperatures used, the carbon compounds are more easily decomposed than the corresponding silicon compounds. Depending on the temperature used, the atomic ratio of silicon to carbon must be selected within the limits of about 5.1 to 100: 1 , the higher number for higher temperatures, that is to say about 20001.degree. C., applies. A temperature of around 13001 C should be selected for the ratio 5: 1. At a ratio of 1: 1 , graphite is also produced and leads to disruptions in the structure of the single crystal, which cannot be reversed and which make the silicon carbide produced unusable for semiconductor technology. At least further procedural steps must follow.

The invention is to be explained in more detail using an exemplary embodiment from which further details and advantages of the method according to the invention emerge. The drawing shows a reaction space in which the method according to the invention can be carried out. A bell-shaped upper part 2, which can for example consist of quartz, rests in a gas-tight manner on a lower part 3. The lower part 3 can for example consist of metal and be provided with a cooling circuit. A pipe 4 through which the gaseous silicon and carbon compounds are fed leads into the reaction chamber. The residual gases, which can optionally be worked up again, are discharged through a larger pipe 5. By arranging the thin pipe 4 inside the exhaust pipe 5 , the inflowing gas mixture can be preheated. Two rod-shaped supports 6 and 7 are arranged in the reaction space and are held in holders in the bottom of the vessel. At the upper end they are connected to one another with the aid of a bridge-shaped part 8.

The carriers can be heated in various ways; for example, induction heating or radiant heating can be provided. In the illustrated embodiment, a heater is provided by means of direct current passage. Lines lead from a power source 9 to the support rods 6 and 7, which are connected to one another in a current-conducting manner by the bridge-shaped part 8. Feedthroughs 10 and 11 through the base-shaped part 3 also serve as holders for the support rods. The power source 9 can be a direct current source or also an alternating current source. If necessary, it can be a regulated power source. A controllable resistor 12 is shown in the line, which is intended to symbolize the possibility of regulating the electrical heating device. Appropriately, the support rods are regulated to a constant temperature by measuring the temperature from outside through the quartz wall of the bell 2 by means of pyrometers and regulating the electrical heating to a constant temperature.

Depending on the material used, the support rods can optionally a preheating of the support rods, e.g. B. by means of radiant heating, provided be, which preheats the support rods up to power consumption; for example is High-purity silicon practically non-conductive when cold, so it must therefore be preheated will.

The carriers 6 and 7 can be, for example, graphite, tantalum, silicon or even silicon carbide. The bridge-shaped part 8 can also be made from these materials. After the silicon carbide has been deposited, the carrier material originally present, if it is not silicon carbide itself, can be removed mechanically or chemically dissolved out of the silicon carbide, e.g. B. with the help of an etching solution, which consists of a mixture of hydrofluoric acid and nitric acid. Hot caustic soda can also be used for this.

It is particularly favorable when in the method according to the invention as a carrier body made of silicon carbide can be used, in particular monocrystalline Carriers on which the growing material then also grows monocrystalline.

The silicon carbide single crystal carrier is expediently inserted into the Holder used so that its axis has a preferred crystallographic direction is equivalent to. It is advantageous in one before feeding the output connections annealed pure hydrogen atmosphere.

Since silicon carbide is difficult to work with, the carrier bodies are used preferably the shape of flat boards so that the deposited layers have the shape of flat, disc-shaped bodies.

In order to achieve a pn-junction in the silicon carbide, one can add the reaction mixture add doping substances in a known manner. It can e.g. B. for the purpose of doping from the gas phase the silicon halide directly phosphorus chloride (PCI.3), boron bromide (BBr.) Or boron chloride (BC4) can be added in a certain order. Possibly can also be doped additionally or only the carrier material. Other dopants are amines, phosphines and aluminum or boron alkyls.

By deposition on board-shaped support bodies from another In this way, material that is later removed can be used as semiconductor components Produce even with very thin layers. The thickness of the inventive -Procedure deposited silicon carbide layer can be orientated preliminary tests by choosing the duration of exposure and concentration of the reactants as well adjust the reaction temperature reproducibly up to almost any small thickness.

The silicon halides known for this purpose, such as, for example, silicon tetrachloride or silicochloroform, can be used as starting compounds. The corresponding bromides and iodides can also be used. In a known manner, suitable hydrocarbons are either pure hydrocarbons or halogenated, in particular low halogenated, hydrocarbons or hydrocarbon derivatives. Low halogenated hydrocarbons are to be understood as meaning those in which the atomic ratio of halogen to hydrogen in the carbon compound is less than or at most equal to 1 . In particular, the lower hydrocarbons such. B. methane, ethane, propane, ethylene and acetylene in question. Suitably, mixtures are used of various hydrocarbons and Kohlenwasserstoffabkömmlingen, wherein the waste z kömmlinge. B. may contain one of the dopants mentioned.

As a carrier or diluent gas, among other things, the noble gases such. B. argon or chlorine or hydrogen halide, such as hydrogen chloride or hydrogen bromide, can be used. Preferably, hydrogen can be used in a manner known per se, which, when the silicon halides decompose with the split off halogens, forms compounds which are removed from the reaction space with the exhaust gas. The molar dilution ratio of silicon halide to hydrogen is expediently chosen to be relatively high, e.g. B. 1:15. A restrictive condition for the hydrocarbons or hydrocarbon derivatives used is that only those may be used which do not form water during thermal decomposition or reduction by hydrogen.

Example 1 In the reaction chamber support rods 6 and 7 are made of silicon used and heated to about 1300 "C. Through the nozzle attached to the end of the tube 4, a flow of 200 l / hour is generated. Argon supplied to the reactants silicochloroform in an amount of 130 g / hour. and methane in an amount of 1 g / hour. can be added. Silicon single crystal rods are advantageously used. Initially, only silicon deposition is carried out by adding only silicochloroform to the diluent gas. By slowly increasing the addition of methane up to the specified amount, it can be achieved that in the gradual transition via a mixed crystal, silicon carbide is finally precipitated in monocrystalline form as well.

Beispie12 Silicon carbide carriers are inserted into the reaction chamber and heated to around 18001 C. A flow of 200 l / hour is passed through the nozzle. Hydrogen as supplied, the silicon tetrachloride (SiC14) in an amount of 100 g / h. and carbon tetrachloride (CCI4) at 1.8g / hour. are mixed in.

Claims (2)

Claims: 1. A method for producing high-purity silicon carbide for semiconductor devices by thermal decomposition of a gaseous silicon compound and gaseous hydrocarbons or hydrocarbon derivatives that do not form water during decomposition or reduction, in the presence of a diluent gas, in particular hydrogen, the carbide on a is deposited over 11501 C heated carrier, d a d g e h URC -kennzeichnet that an atomic ratio of silicon contained in the silicon halide to that contained in the hydrocarbon carbon is between 5: 1 is selected: 1 to 100. 2. The method according to claim 1, characterized in that the temperature of the carrier is set to about 1300 ° C and the ratio of silicon to carbon to about 5 . 3. The method according to claim 1, characterized in that a carrier made of silicon carbide is used. 4. The method according spoke 1, characterized in that acetylene, methane or propane is used as the hydrocarbon. 5. The method according to claim 1, characterized in that a carrier made of silicon is used, which is dissolved out after the deposition. 6. The method according to claim 3, characterized in that a single crystal is used as the carrier. 7. The method according to claim 1, characterized in that the carrier is heated by direct passage of current. 8. The method according to claim 1, characterized in that the reaction gas is an alkyl of an element of III. Group of the periodic table is added. 9. The method according to claim 1, characterized in that an amine is added to the reaction gas. References Considered: Silicon Carbide, by O'Connor and Smiltens, Pergamon Press, 1960, pp. 67, 75 and 76.