WO1997040527A1

WO1997040527A1 - Process for producing a doped area in a semiconductor substrate

Info

Publication number: WO1997040527A1
Application number: PCT/DE1997/000707
Authority: WO
Inventors: Ulrike GRÜNING; Volker Lehmann; Reinhard Stengl; Hermann Wendt; Herbert Schäfer
Original assignee: Siemens Aktiengesellschaft
Priority date: 1996-04-22
Filing date: 1997-04-07
Publication date: 1997-10-30

Abstract

This invention concerns a process for producing a doped area in a semiconductor substrate (1) by producing a trench (3) which is filled in with an epitaxially grown, doped semiconductor layer (4, 5). The process is suitable for producing more deeply doped areas, so-called 'vertical doping', as well as many little doped p-n junctions as they are for example needed in new power components.

Description

description

Method for producing a doped region in a semiconductor substrate

The semiconductor technology is based on the production of doped regions in crystalline semiconductor substrates. In the process, dopant is introduced into the semiconductor substrate, so that the electrical properties change. However, the crystalline structure of the semiconductor substrate remains essentially unchanged in the doped regions.

Doped areas are usually produced by diffusion or implantation. The dopant introduced is then electrically activated in a tempering step. Since the diffusion in the semiconductor substrate is essentially isotropic, doped regions produced by diffusion have a lateral extent which is essentially equal to or greater than their depth. The depth of doped areas created by implantation depends on the energy with which the implantation takes place. Doped areas with a depth of up to approximately 5 μm can be produced by implantation.

For various technical applications, for example for power components, especially power MOSFETs, or for micromechanical applications, doped regions are required which have a greater depth than width. Such doped areas are often referred to as vertical doping. In the limiting case, such doped regions should have a depth corresponding to the thickness of the semiconductor substrate.

The invention is based on the problem of specifying a method for producing a doped region in a semiconductor substrate, with which doped regions of great depth can be produced. This problem is solved by a method according to claim 1. Further refinements of the invention emerge from the remaining claims.

In the method, a trench is produced in a main surface of a semiconductor substrate. A doped layer is then grown epitaxially. In the epitaxial process, dopant is added so that the doped layer grows up in situ. The doped layer fills the trench. The part of the doped layer arranged in the trench forms the doped region. In this case, the dimensions of the doped region depend exclusively on the geometry of the trench. The application of the method can be used particularly advantageously for the production of doped regions with great depth. In particular, doped regions with a depth of 5 μm to 500 μm, for example 200 μm and a width of 0.2 μm to 40 μm, for example 1 μm, can be realized. The ratio of depth to width (aspect ratio) is greater than 1.

Since the trench is filled by the doped layer, which is grown epitaxially, the doped region has essentially the same crystal structure as the semiconductor substrate.

In the method according to the invention, doped regions both of the same conductivity type as the substrate and of the opposite conductivity type as the substrate can be produced.

Since epitaxial processes are carried out at temperatures significantly above 500 ° C., the dopants are built into the doped layer and electrically activated during epitaxial growth of the doped layers. A separate one

Tempering step for electrical activation of the dopants is therefore not necessary in the method according to the invention.

Parts of the doped layer located on the main surface of the semiconductor substrate can be removed by anisotropic etching or chemical / mechanical polishing.

The trench has any cross section parallel to the main surface. In particular, the trench can have a circular, square, rectangular, elongated, strip-shaped or annular cross section parallel to the main surface.

The trench is made, for example, by anisotropic etching using a mask. Alternatively, the trench is produced by electrochemical etching.

In the case of electrochemical etching, the semiconductor substrate is brought into contact with an electrolyte with the main surface. The semiconductor substrate is connected to the electrolyte as an anode. As a result, minority charge carriers move in the semiconductor substrate to the main surface in contact with the electrolyte. A space charge zone forms on this surface. Since the field strength in the area of depressions in the surface is greater than outside it, the minority charge carriers preferably move to these points. This leads to a structuring of the surface. The deeper an initially small unevenness becomes due to the etching, the more minority charge carriers move there because of the increased field strength and the stronger the etching attack at this point. In this way, holes grow in the main surface of the semiconductor substrate.

Holes that cross the entire semiconductor substrate can be produced by means of electrochemical etching. The arrangement of the holes can be predetermined by providing the main surface with recesses on which the etching attack begins with electrochemical etching. The depressions are formed, for example, by masked etching with an alkaline etching. In order to produce strip-shaped or ring-shaped trenches, these depressions are arranged in such a way that adjacent holes grow together during electrochemical etching.

When using a semiconductor substrate which comprises n-doped monocrystalline silicon at least in the region of the main surface, the electrochemical etching takes place in a fluoride-containing, acidic electrolyte.

The epitaxy process is preferably carried out in a parameter range in which the epitaxy is limited by the surface reaction. This ensures that the doped layer grows uniformly on the entire surface, that is to say both in the area of the main surface and in the trench.

The epitaxial process in the temperature range between 700 ° and 900 °, preferably 850 ° C., in the pressure range between 1 and 20 torr, preferably 10 torr, with at least water is preferably carried out on a semiconductor substrate which comprises monocrystalline silicon at least in the region of the main surface ¬ substance and dichlorosilane process gas performed. The flow of hydrogen in the range between 30 and 50 slm (standard liters per minute), preferably 40 slm, and the flow of dichlorosilane in the range between 50 and 250 sccm, preferably 200 sccm (standard cubic centimeter). The dopant is added in the form of diborane, phosphorus or arsine. The dopant is added from a storage container which contains diluted dopant in a carrier gas, for example H2 or Ar. With a proportion of the dopant of 100 ppm in a gas mixture, the flow rate of the gas mixture is set in the range between 0.5 sccm and 6 sccm, preferably 3 sccm. With these process parameters, the epitaxy takes place with limited surface reaction. The trench preferably has a slightly conical cross section. This means that the side walls of the trench are tilted a few degrees against the normal of the main surface. This tilt angle is preferably 0.01 ° to 3 °. This ensures a void-free filling of the trench.

The method can advantageously be used in the production of power components with deep-reaching doped areas and / or many adjacent low-doped pn junctions.

The invention is explained in more detail below on the basis of an exemplary embodiment and the figures.

Figure 1 shows a substrate with trenches.

FIG. 2 shows the substrate with an epitaxially grown first doped layer and an epitaxially grown second doped layer.

Figure 3 shows the substrate after removing the on the

Main surface arranged parts of the first doped layer and the second doped layer.

A substrate 1 made of, for example, n-doped, monocrystalline silicon is brought into contact with an electrolyte with a main surface 2. In the main surface 2, the substrate 1 has depressions which are formed, for example, with the aid of a photoresist mask and subsequent alkaline etching with KOH.

The electrolyte contains fluoride and is acidic. It contains a hydrofluoric acid concentration of 1 to 50 percent by weight, preferably 6 percent by weight. An oxidizing agent, for example hydrogen peroxide, can be added to the electrolyte to suppress the development of hydrogen bubbles on the main surface 2 of the substrate 1. A voltage of, for example, 3 volts is applied between the substrate 1 and the electrolytes. The substrate 1, which has a specific resistance of 5 Ωcm, for example, is connected as an anode. The substrate 1 is illuminated from a surface opposite the main surface 2. A current density of 10 mA / cm * ^ is set in the substrate 1 by the illumination.

With these process parameters, trenches 3 are etched into the main surface 2 (see FIG. 1). The trenches 3 have an essentially circular cross section in the region of the main surface 2. In the area of the main surface 2, the trenches 3 have a diameter of, for example, 1 μm. The trenches 3 are produced with a depth of, for example, 200 μm. The trenches 3 have slightly conical side walls which are tilted by 0.1 ° with respect to the normal to the main surface 2 (this tilting is not shown in the figures).

An epitaxial process is then carried out, in which a first doped layer 4 is grown on the main surface 2 and the surface of the trenches 3. The epitaxial process is carried out, for example, at 850 ° C., 10 torr with 40 slm hydrogen and 200 sccm dichlorosilane. Phosphon or arsine from a gas mixture containing H2 or Ar and 100 ppm dopant is added as a dopant with a flow rate of 3 sccm. The first doped layer 4 is n ⁺ -doped with a dopant concentration of 10 ^ ⁷ cm ^" 3. The first doped layer 4 is grown in a layer thickness of, for example, 0.2 μm. Since the epitaxy process is in the parameter range used is surface reaction limited, the first doped layer 4 grows with an essentially constant layer thickness.

A second doped layer 5 is grown on the first doped layer 4 in a further epistemic process. The second epitaxial process is carried out at 850 ° C., 10 torr with 40 slm hydrogen and 200 sccm dichlorosilane. In the second epitaxial process, diborane from a gas mixture containing H2 or Ar and 100 ppm diborane is added at a flow rate of 3 sccm. The second doped layer 5 is p ⁺ -doped with a dopant concentration of, for example, 10- ¹ - ⁷ cm ^" 3. The second doped layer 5 is grown in a layer thickness of, for example, 0.3 μm.

The first doped layer 4 and the second doped layer 5 completely fill the trenches 3 (see FIG. 2).

The second main surface of the substrate 1 is then exposed outside the trenches 3 by chemical / mechanical polishing (see FIG. 3). In this way, p ⁺ -doped regions 5 'and n ⁺ -doped regions 4' are formed in the region of the trenches 3. The crystal quality in the p ⁺ -doped regions 5 'and in the n ⁺ -doped regions 4' is comparable to the crystal quality of the substrate 1. The n ⁺ -doped regions 4 'and the p ⁺ -doped regions 5' and the parts of the substrate 1 arranged in between form a dense sequence of pn junctions. The p ⁺ -doped regions 5 'and the ^ -doped regions 4 "extend deeper into the substrate 1 than corresponds to their lateral dimensions.

The exemplary embodiment described can be modified in that the n ⁺ -doped layer 4 completely fills the trenches 3 or that the n ⁺ -doped layer 4 is omitted and the p ⁺ -doped layer 5 is grown on the surface of the trenches 3 and the trenches 3 completely filled.

Claims

claims

1. Process for producing a doped region in a semiconductor substrate,

- in which a trench (3) is produced in a main surface (2) of the semiconductor substrate (1),

- in which in an epitaxial process with the addition of dopant a doped layer (4, 5) is grown, which fills the trench (3) and whose part arranged in the trench (3) contains the doped region (4 ', 5' ) forms.

2. The method according to claim 1, wherein the trench (3) has a depth that is greater than at least one linear extension of the trench (3) parallel to the main surface (2).

3. The method according to claim 1 or 2, wherein the trench (3) has flanks which are inclined to the normal surface of the main surface (2) by 0.01 ° to 3 °.

4. The method according to any one of claims 1 to 3, wherein the semiconductor substrate (1) comprises at least in the region of the main surface (2) monocrystalline silicon.

5. The method according to claim 4, wherein the trench (3) is produced by electrochemical etching in a fluoride-containing, acidic electrolyte which is in contact with the main surface (2) and against which the substrate (1) is connected as an anode.

6. The method of claim 4 or 5, wherein the epitaxial process in the temperature range between 700 and 900 ° C, in the pressure range between 1 and 20 torr with a hydrogen and dichlorosilane comprising process gas, the flow rate of hydrogen between 30 and 50 slm (Standard liters per minute) and the flow rate of the dichlorosilane in the range between 50 and 250 sccm

(Standard cubic centimeter) is set and in which diborane, arsine or phosphine is added as the dopant.

7. The method according to any one of claims 1 to 6,

- in which several trenches (3) are created in the main surface (2), the spacing of which is less than their depth,

- In which the epitaxially grown, doped layer (4, 5) fills the trenches and thus forms a doped region (4 ', 5') in each trench.