DE2723500C2 - Process for depositing silicon dioxide layers on semiconductor devices - Google Patents

Description

The invention relates to a method according to the preamble of claim 1. Such a method is known from "Journal of the Electrochemical Society" Feb. 64, pp. 206-209. The carrier gas is the known process with a deposition temperature of approx. 1200 ° C hydrogen used, which at the same time is a reactant. In the known method, only one pane is coated at a time. Further a process for the pyrolytic deposition of silicon dioxide layers is known in which the silane (S1H4) has been chemically converted. This process also has the disadvantage that the reactors are relatively small Have recording capacities. In addition, the layers produced in this way did not have the desired uniformity the thick one. Furthermore, working with silane is associated with safety problems, since various There is a risk of explosion for silanes with a higher concentration. This is especially true for that as well used dichlorosilane (Si ^ Cb) -

From the journal "TELEFUNKEN Röhre", Dec. 67, No. 47, pp. 103-122, there is also an oxidation process known at temperatures above 1000 ° C and normal pressure, with silicon tetrachloride as reaction gases and steam can be used. The evenness of the deposited layers is, however still satisfactory with this method.

From US-PS 36 50 929 a plasma oxidation process under negative pressure is known. The negative pressure is in this case only required to enable gas discharge. The oxidation takes place with the help of a Oxygen flow. In this process, too, only individual panes are coated.

The present invention is based on the object of a deposition method according to the preamble of claim 1 to indicate that allows a large production capacity and evenly thick, good reproducible layers provides This object is achieved by a method according to the characterizing part of claim 1 solved

A method is known from DE-OS 24 31 917 in which at a pressure of 10-650 mbar and a temperature of 600-900 ° K glass layers are deposited from a gas mixture of silane and oxygen will. However, this process does not produce any aggressive by-products.

Furthermore, from US-PS 36 15 956 a method is known in the case of semiconductor wafers standing vertically and parallel to one another in large numbers in an elongated manner Reaction vessel are arranged. However, this is a plasma etching process only small amounts of silicon tetrachloride are produced at the prevailing negative pressure.

Nitrogen is preferably used as the carrier gas for the water vapor. Nitrogen as a carrier gas for other reaction partners are already known from DE-OS 20 52 221 and DE-OS 24 31 917

In a device suitable for carrying out the method, one end of this tube is connected to the controllable supply means for the various necessary gases connected. The inventive Process is particularly useful for the production of masking and / or passivation layers from silicon dioxide suitable on semiconductor wafers. These can therefore be layers that act as masks for diffusion processes or serve as a carrier for interconnect systems.

In the method according to the invention it is important that a filter is connected upstream of the vacuum pump will. It has been shown that if this filter is not used, the vacuum pump is destroyed in a very short time will. This filter is divided into a cooling filter and a dust filter.

The method according to the invention is also intended to be based on a suitable exemplary embodiment are explained in more detail.

In the figure is an elongated separation tube 1 shown, which is preferably made of quartz and with a heating coil 2 to the desired temperature can be brought. Approx. 400 to 500 semiconductor wafers 3 can stand perpendicularly in parallel in the tube be arranged to each other. This capacity exceeds that of conventional silane reactors by a factor of 20. At one end of the pipe are flow meters for feeding the necessary Gases connected. The flow rate of the silicon tetrachloride is set with one flow meter, while the other flow meter regulates the amount of hot steam supplied will. The carrier gas for the water vapor is nitrogen, which is passed through heated or boiling water will.

At the other end of the separation pipe a pressure regulator is connected to the irregularities the vacuum pump compensates. Filters are connected between the pressure regulator and the vacuum pump to allow the Cool the extracted gas mixture and remove dust particles, for example from silicon dioxide or silicic acid particles, to free. These dust particles must not get into the vacuum pump, otherwise they will already after would be mechanically destroyed in a short time.

In a preferred embodiment, 200 mg / min of silicon tetrachloride was added to the separation tube and approx. 50 to 100 l / h through heated water

ter nitrogen supplied. In the deposition tube is at a temperature between 85O ⁰ C and 925 ° C prevailed a pressure of 0.65 to 1.95 mbar. A silicon dioxide layer is deposited on the semiconductor wafers at a growth rate of 10 to 50 nm / min. Layer thicknesses between 0.1 and 4 μm were generated. The deposition rate can be varied between approx. 2 to 200 nm / min by changing the furnace temperature, gas composition and the gas temperature. During the deposition process, silicon tetrachloride reacts with water vapor and forms silicon dioxide and other volatile gases.

With the method described, the fluctuations in the uniformity of the layer thickness could be avoided be limited to less than 3%. Even with successive batches, the fluctuations were in the layer thickness below 5%.

The new manufacturing process for the silicon dioxide layers is very inexpensive, since the equipment costs and the material costs for the gases are extremely low . Since, in addition, no safety precautions are necessary and the throughflow capacity - as already mentioned - could be increased considerably, the production costs could be reduced by a factor of 40 compared to known methods.

1 sheet of drawings

30th

J5

40

45

50

Claims (3)

Patent claims: 1. A method for depositing silicon dioxide layers on semiconductor devices, in which the Semiconductor wafers a constant gas stream of silicon tetrachloride, water vapor and an additional Carrier gas can be exposed to high temperatures until it settles on the surfaces of the semiconductor wafers have formed silicon dioxide layers of a certain thickness, thereby characterized in that the deposition of 0.1-4; in thick layers in an elongated Tube with a large number of semiconductor wafers arranged vertically and parallel to one another at a pressure of approx. 0.013-6.7 mbar and at takes place at a temperature between 600-925 ° C, and that the constant gas flow with the help of a cooling filter and a dust filter to the gas outlet opening the vacuum pump connected to the pipe is maintained. 2. The method according to claim 1, characterized in that the carrier gas for the water vapor Nitrogen is used. 3. The method according to claim 1 or 2, characterized in that the separation pipe approx. 200 mg / min silicon tetrachloride and approx. 50-100 l / h nitrogen passed through heated water with a the temperature of 850 to 925 ° C prevailing in the separation vessel is supplied.