EP1019953A1

EP1019953A1 - Method for thermal curing of implantation-doped silicon carbide semiconductors

Info

Publication number: EP1019953A1
Application number: EP98955323A
Authority: EP
Inventors: Karlheinz HÖLZLEIN; Roland Rupp; Arno Wiedenhofer
Original assignee: Infineon Technologies AG
Current assignee: Infineon Technologies AG
Priority date: 1997-09-30
Filing date: 1998-09-14
Publication date: 2000-07-19
Also published as: CN1272957A; US6406983B1; JP2001518706A; WO1999017345A1

Abstract

An implantation-doped silicon carbide conductor (10i) is thermally cured in a gas flow (12) supplying practically no carbon to said conductor (10i).In one advantageous embodiment, the container (13), carrier (16), radiation shields (4,5) and the base plate (17) are made of metal or a metal compound, e.g. tantalum or tantalum carbide, at least in the places which come into contact with the gas flow (12).

Description

description

Process for the thermal annealing of silicon carbide semiconductors doped by implantation

The invention relates to a method for the thermal annealing of at least one silicon carbide semiconductor doped by implantation in a gas stream.

Silicon carbide (SiC), preferably in monocrystalline form, is a semiconductor material with excellent physical properties, which make this semiconductor material particularly interesting for optoelectronics, high-temperature electronics and power electronics. While silicon carbide light-emitting diodes are already available on the market, there are as yet no commercial power semiconductor components based on silicon carbide. This is primarily due to the complex and expensive manufacture of suitable silicon carbide substrates (wafers) and the process technology, which is more difficult than that of silicon.

One of the problems is the doping of single-crystal silicon carbide. Because of the high temperatures required of over 1800 ° C., doping of silicon carbide by diffusion is practically impossible, unlike silicon. Therefore, single-crystal silicon carbide is doped either by adding dopants during growth, especially during sublimation growth (PVD) or chemical vapor deposition (CVD), or by implantation of dopant ions (ion implantation).

The implantation of dopant ions in single-crystalline silicon carbide substrates or in a previously grown silicon carbide epitaxial layer allows a targeted lateral variation of the dopant concentration, so that the production of semiconductor components with a planar structured surface is possible. This is a basic requirement for the Most semiconductor components are problematic. However, problematic with the doping by implantation are crystal defects (lattice defects, crystal disorder) which arise from the dopant atoms implanted with high kinetic energy in the silicon carbide crystal of the epitaxial layer and which have the electronic properties of the implanted semiconductor region and thus of the whole Component deteriorate. In addition, the dopant atoms or atomic trunks are not optimally built into the silicon carbide crystal lattice after the implantation and are therefore only partially electrically activated.

Methods have therefore been developed by means of which the crystal defects resulting from the implantation can be healed by thermal treatment and at the same time a high degree of activation of the dopant atoms can be achieved (so-called thermal healing processes or "thermal annealing").

From "IEEE Electronic Device Letters", vol. 13, 1992, pages

639 to 641, a method for the thermal annealing of a 6H silicon carbide semiconductor region n-doped by implantation of nitrogen ions at high implantation temperatures between 500 ° C. and 1000 ° C. is known in a 6H silicon carbide epitaxial layer doped with aluminum. In this process, the 6H silicon carbide semiconductor is treated at a constant annealing temperature between 1100 ° C and 1500 ° C in an argon atmosphere. In order to avoid destruction of the surface by uncontrolled evaporation with the formation of craters and cavities, the 6H silicon carbide semiconductor is placed in a crucible made of silicon carbide. During the heat treatment, the surface of the 6H silicon carbide semiconductor is in equilibrium with the silicon carbide atmosphere inside the crucible.

In contrast, in "Appli ed Surface Science", Vol. 99, 1996, pages 27 to 33, the influence of the gas composition during cooling Process of a chemical vapor deposition process (LPCVD = Low Pressure Chemical Vapor Deposition) described on silicon carbide semiconductors. The cooling process starts at a maximum temperature of 1450 ° C, which is therefore comparable to the temperatures during thermal healing after the ion implantation. The results obtained can therefore also be transferred to the thermal healing processes after the ion implantation. In the studies cited, it was found that at temperatures above 1000 ° C. in a vacuum or under protective gas, the near-surface silicon carbide atomic layers of silicon become poor, and that a thin graphite layer can form on the surface of the silicon carbide semiconductor. If, on the other hand, the same process is carried out under a pure hydrogen atmosphere, the result is an almost stoichiometric surface.

The invention is based on the object of specifying an improved method compared to the prior art for the thermal annealing of silicon carbide semiconductors doped by implantation, in which the formation or the assembly of undesired crystallographically oriented stages is reduced.

This object is achieved according to the invention with the features of claim 1. The healing process must therefore be designed in such a way that practically no carbon is supplied to the at least one silicon carbide semiconductor via the gas stream. In this context, “practically no carbon” means a smaller proportion of carbon than that which corresponds to the equilibrium partial pressure of carbon or carbon-containing components (eg SiC ₂ ) over the silicon carbide semiconductor at the respective process temperature.

The invention is based on the knowledge that the misaligned silicon carbide surfaces of, for example, epitaxially applied layers or of single-crystalline subrates, are only present in the ideal case One or two monolayer high, crystallographically oriented steps due to a thermally activated surface redistribution undesirably up to a step height of about 50 nm (step benching) if the silicon carbide semiconductor is in equilibrium with a silicon carbide atmosphere during the thermal annealing process, or the gas stream supplied contains at least comparable carbon fractions to this state of equilibrium. In this process, many small, few high crystallographic stages conglomerate. The small, approximately two monolayers, crystallographically oriented steps are an inevitable consequence of the misorientation of the basic silicon carbide crystals necessary for epitaxial layer growth. It has been found that by reducing the proportion of foreign carbon in the gas stream, ie the proportion of carbon that is fed to the silicon carbide semiconductor from the outside, the step growth described can be considerably restricted.

When the gas flow is designed in accordance with the invention, step heights result after the thermal annealing, which are significantly lower than the prior art, in particular at least a factor of 3 lower.

Advantageous refinements and developments of the thermal healing process according to the invention result from the claims dependent on claim 1.

In a particularly advantageous embodiment, at least the surface of the doped region of the silicon carbide semiconductor is exposed to a gas stream which preferably contains at least one inert gas and / or nitrogen and / or hydrogen. The gas stream composition can be changed during annealing, for example from an inert gas composition to a hydrogen-containing composition or even to practically pure hydrogen. Argon or helium with volu- proportions of up to almost 100%. A preferred variant of the process control consists in heating in an inert gas stream, then keeping it at an approximately constant maximum temperature and then in a gas stream with a hydrogen content of typically at least

50%, in particular more than 80% and preferably over 95% is cooled. By cooling in a hydrogen atmosphere, a stoichiometrically almost intact surface of the silicon carbide semiconductor is achieved, whereas cooling in e.g. Argon atmosphere, possibly due to silicon depletion, can lead to a thin graphite layer on the surface of the silicon carbide semiconductor.

In order to prevent dopant atoms from escaping from the silicon carbide semiconductor, in a further advantageous embodiment atoms can be added to the gas stream under a predetermined gas partial pressure, which atoms were also used for doping.

The flow rate of the gas stream is preferably set between approximately 0.5 cm / s and approximately 60 cm / s, in particular between 5 cm / s and 25 cm / s. It has been shown that a silicon carbide semiconductor which has been annealed under such a gas stream has a significantly better surface area than a silicon carbide semiconductor which has been annealed in a gas stream at a different flow rate. Flowing the silicon carbide semiconductor during the annealing has the advantage that, in contrast to the known annealing methods, the surface has a morphologically good quality despite the high temperatures, and the crystallographic stages resulting from the misorientation of the silicon carbide surface essentially are preserved and do not assemble into larger steps, and there are no other surface roughness. The above-mentioned preferred range for the flow rate ensures that the flow rate is on the one hand small enough to prevent inadmissible cooling of the silicon carbide half to avoid conductor, and on the other hand large enough to remove carbon and silicon atoms emerging from the silicon carbide semiconductor, so that they cannot contribute to undesired step growth.

The static process pressure in a region of the gas atmosphere adjacent to at least the silicon carbide semiconductor is generally advantageously set between approximately 5000 Pa and approximately 100000 Pa (normal pressure) and preferably between approximately 10000 Pa and approximately 50,000 Pa. The set negative pressure ensures particularly good suppression of the undesired growth of the crystallographically oriented steps.

In a further advantageous embodiment, the silicon carbide semiconductor is arranged in the interior of a container, which can preferably be heated via an HF (high-frequency) induction coil. The silicon carbide semiconductor is preferably held in the interior of the container by a carrier. In addition, at least one radiation shield is preferably placed in the interior of the container in relation to the gas flow direction in front of and behind the carrier in order to prevent undesired heat radiation from the interior of the container. Openings for the passage of the gas stream are preferably provided in the radiation shields. At least in the areas that come into contact with the gas flow, the carrier, the radiation shields and the container, for example at least parts of the inner wall of the container, advantageously consist of at least one metal or at least one metal compound or are at least lined or coated with the same. The metal or the metal compound should advantageously only melt above 1800 ° C. due to the high process temperatures during thermal annealing. The metal or the metal compound should advantageously have a vapor pressure of less than 10 ^"2 Pa (approx. 10 ^{" 7} Atm) at the maximum temperature of 1800 ° C. The metal or metal compound should be in the gas stream because of the intended hydrogen content advantageously be resistant to hydrogen. Metals or metal compounds which contain at least one of the materials tantalum, tungsten, molybdenum, niobium, rhenium, osmium, iridium or their carbides can thus be used particularly advantageously. Parts of the container that do not come into contact with the part of the gas stream that reaches the silicon carbide semiconductor can also be made of other materials such as graphite or silicon carbide. All parts which have not been listed so far but which may be present in the hot area and which come into contact with the gas stream should likewise preferably consist of the advantageous metals or metal compounds mentioned or at least be coated with the same. The described advantageous selection of materials ensures that the gas stream flowing past does not remove any carbon atoms from the contact surfaces, such as the inner wall of the container or the support surface, or absorb escaped carbon atoms and leads them to the silicon carbide semiconductor.

In a particularly advantageous embodiment of the method, a silicon carbide semiconductor doped by implantation is brought to a maximum temperature of at least 1000 ° C. by supplying heat. The increase in temperature over time (heating rate) is generally limited to a maximum of 100 ° C./min, preferably to a maximum of 30 ° C./min, during this heating process.

The maximum temperature is advantageously set between 1100 ° C and 1800 ° C, preferably between 1400 ° C and 1750 ° C.

The silicon carbide semiconductor is advantageously kept at least approximately at the maximum temperature for a predetermined time interval of preferably between 2 min and 60 min, in particular between 15 min and 30 min. This high-temperature plateau brings an improvement in the degree of activation of dopants in silicon carbide semiconductors. The cooling rate is advantageously limited to a maximum of 100 ° C / min, in particular to a maximum of 30 ° C / min. The slow cooling process expediently ends at an intermediate temperature, which is preferably below 600 ° C. The limitation of the rate of temperature change (heating and cooling rates) leads to improved electrical properties of the silicon carbide semiconductor doped by implantation and then healed.

The rate of heating and / or cooling does not have to be constant, but can advantageously also vary within ranges which are determined by an upper limit of 100 ° C / min and in particular by an upper limit of 30 ° C / min.

In a special development of the method, the temperature of the silicon carbide semiconductor is kept at least once at a predetermined temperature level during the heating and cooling process. The rate of warming up or cooling down is practically 0 ° C./min.

Exemplary embodiments for a thermal healing process according to the invention are explained below with reference to the drawing. 1 shows a perspective view of a container, in the interior of which there is at least one silicon carbide semiconductor for the thermal healing of the lattice defects caused by a previous implantation, and

2 shows the arrangement of FIG. 1 as a longitudinal section. Corresponding parts are provided with the same reference numerals in FIGS. 1 and 2.

1 shows a perspective view of a container 13, in the interior of which, for example, a plurality of silicon carbide semiconductors 10 1 (with i = 1,...) For thermal annealing a previous ion implantation. 2 shows a longitudinal section through the arrangement of FIG. 1. The container 13 is cylindrical in the embodiment shown, but it can also be constructed just as well with a different geometric shape, for example as an elongated cuboid.

The silicon carbide semiconductors 10 1 according to FIGS. 1 and 2 can have been produced before the thermal annealing shown using the following process steps to be carried out in succession:

1. providing a single-crystalline silicon carbide substrate,

2. optional: epitaxial growth of a silicon carbide layer on the substrate,

3. Generation of at least one doping region by possibly repeated, successive implantation of doping atoms.

A sublimation growth process is preferably used to provide the silicon carbide substrate. The silicon carbide substrate essentially consists of a single silicon carbide polytype, in particular of beta silicon carbide (3C silicon carbide, cubic silicon carbide) or one of the polytypes of alpha silicon carbide (hexagonal or rhombohedral silicon carbide). Preferred polytypes for the silicon carbide substrate are the alpha-silicon carbide polytypes 4H, 6H and 15R.

An epitaxy method known per se, preferably an epitaxy by chemical vapor deposition (Chemical Vapor Deposition = CVD), is used to deposit the silicon carbide layer on the silicon carbide substrate. For example, a CVD epitaxy method can be used in accordance with US Pat. No. 5,011,549. Because of the epitaxial growth, the silicon carbide layer, like the silicon carbide substrate, is single-crystalline and thus semiconducting. If the If the growth conditions in epitaxy are set accordingly, the silicon carbide layer is also of a single poly type which is equal to the poly type of the silicon carbide substrate. If the silicon carbide substrate consists of alpha-silicon carbide, it is generally prepared before the silicon carbide layer is deposited, for example by cutting and / or grinding, in such a way that the surface of the substrate provided as the growth surface is at an angle between approximately 1 ° and approximately 12 ° is inclined differently from the (0001) plane, preferably in the direction of one of the <1120> crystal directions. Through such an “off-orientation” of the growth surface with respect to the natural crystal surfaces (basal planes), namely the (0001) crystal surface designated as the silicon side or the (0001) crystal surface designated as the carbon side , in connection with suitable growth temperatures of typically 1500 ° C., the silicon carbide layer is of the same alpha silicon carbide polytype as the silicon carbide substrate and in particular shows no syntax. The silicon carbide layer can be doped by adding appropriate dopant compounds during growth according to a desired conductivity type.

An implantation method is used to generate different doping regions, in which one or more dopants are introduced into the silicon carbide semiconductors 10i. First, the silicon carbide semiconductors 10ι can be provided with implantation masks. The silicon carbide semiconductors 10i are then introduced into an implantation system (not shown). In the implantation system, the surfaces of the silicon carbide semiconductors 10i are bombarded with ions of one or more dopants with energies of typically between 10 keV and a few 100 keV depending on the dopants used and the desired depth of penetration. The silicon carbide semiconductors 10 _± are at temperatures from a range between during implantation about 20 ° C (room temperature) and about 1200 ° C, preferably between about 20 ° C and about 600 ° C.

As a result of the dopant particles penetrating the silicon carbide crystal of the silicon carbide layer with high energy, the silicon carbide crystal lattice in the different doping regions of the silicon carbide semiconductors is damaged 10 _± . For at least partial "repair" and recovery of the crystal defects resulting from the implantation, the silicon carbide semiconductors 10 _{± are} now healed using a thermal annealing process.

For thermal annealing, the silicon carbide semiconductors 10i are introduced into the container 13 of a healing system (not shown, annealing furnace, tempering furnace) and arranged on a carrier 16 in a gas stream 12 in the container 13.

Outside of the container 13, devices for thermal insulation and gas guidance, for example a double-walled water-cooled quartz tube, are not shown in FIGS. 1 and 2. The gas routing device prevents, inter alia, an undesired lateral gas outlet through the wall of the container 13. In addition, a controllable induction heater with at least one HF induction coil 18 is advantageously provided around the container 13 and the devices not shown, by means of which the container 13 is heated inductively. This also uniformly heats the silicon carbide semiconductors 10i in the interior of the container 13. However, resistance heating can also be provided.

The container 13 shown in FIGS. 1 and 2 is advantageously constructed from at least two layers. A container layer 21 forming an outer, load-bearing wall preferably consists of graphite. As a result, the container 13 can be heated particularly well via the HF induction coil, since the good conductivity of graphite leads to the formation of eddy currents favored, and as a result, the container 13 is heated. On the other hand, the outer container layer 21 made of graphite represents a very good black radiator, by means of which the current temperature of the container 13 can be easily detected without contact. In the interior of the container 13, on the other hand, it is more advantageous to provide a coating 20 (see FIG. 2) made of tantalum or tantalum carbide, since the gas stream 12 should advantageously not take up any carbon atoms from the inner wall of the container and supply it to the silicon carbide semiconductors 10i. The thickness of this coating is generally greater than 0.01 mm. In contrast to known full graphite containers or graphite containers coated with silicon carbide, this suppresses the undesired growth of the crystallographic stages. Other metals or metal compounds can also be used for the coating 20, taking into account the special process conditions during thermal annealing. In addition to those already mentioned, metals or metal compounds which contain at least fractions of tungsten, molybdenum, niobium, rhenium, osmium, iridium or their carbides are therefore particularly suitable. Just like the container 13, the carrier 16, which accommodates the silicon carbide semiconductors 10i, consists entirely or at least at the locations that are stripped by the gas stream 12, preferably from the aforementioned metals or metal compounds. The carrier 16 can stand on a base plate 17, which is likewise advantageously provided with a coating 20 made of the aforementioned metals or metal compounds, at least on the surface facing the area through which the gas stream flows. On the front sides of the container 13, radiation shields 14 and 15 with openings 19 are provided in the container interior, through which the gas stream 12 is introduced and discharged. The radiation shields 14 and 15 preferably consist of several individual elements, for example of perforated disks placed one behind the other, which preferably reach as close as possible to the inner wall of the container. As a result, they are determined to protect the interior of the container from heat loss through radiation. especially good. The radiation shields 14 and 15 again preferably consist of the aforementioned metals or metal compounds.

In another preferred embodiment, not shown, the container 13 and the base plate 17 are not formed in two layers, the one layer then consisting of the aforementioned metals or metal compounds.

It has proven to be particularly advantageous if the gas stream 12 is preheated when it passes the radiation shield 14, for example by advantageous shaping of the individual elements, so that the gas stream 12 does not undesirably cool the silicon carbide semiconductors 10i. Because by adhering to the temperature curves recognized as advantageous on the silicon carbide semiconductors 10ι, particularly good results can be achieved when the implantation damage is healed. The result of this is an improved blocking behavior of p-n junctions, which may have been introduced, for example, into the silicon carbide semiconductors 10 in the preceding doping processes, not shown here.

Instead of the illustrated in FIGS 1 and 2 arrangement in a row, the silicon carbide semiconductor 10 _± may also be placed laterally offset to each other preferably. In a further embodiment, not shown, the surfaces of the silicon carbide semiconductors 10j to be annealed _. Instead of the vertical orientation shown in FIGS. 1 and 2, it can also advantageously be rotated, inclined or in particular arranged parallel to the main flow direction of the gas stream 12. These embodiments lead to a better and more uniform flow around, so that the carbon and silicon atoms emerging from the silicon carbide semiconductors 10i can be more easily detected and transported away by the gas stream 12. The undesirable growth of the crystallographic Oriented steps are thus avoided. The parallel embodiment is particularly easy to achieve if the support 16 shown in FIG. 1 is rotated by 90 ° in its orientation relative to the gas flow 12. In a further embodiment, not shown, one does not need a separate carrier 16 for holding the silicon carbide semiconductors 10i. In this variant, the silicon carbide semiconductors 10 are advantageously in recesses in the base plate 17, so that the surfaces of the silicon carbide semiconductors 10i to be healed are in turn oriented parallel to the main flow direction of the gas stream 12. In an advantageous variant of this embodiment, not shown, a plurality of base plates 17 with recesses are stacked one above the other, so that a higher throughput can be achieved.

In the embodiment shown with the gas flow 12 arranged perpendicularly to the silicon carbide semiconductor 10ι, it has proven to be particularly advantageous to at least the first and the last mounting position of the carrier 16 with dummy silicon carbide semiconductors 11, which actually should not be subjected to a healing process equip. These dummy silicon carbide semiconductor 11 serve to treat all be annealed silicon carbide semiconductor 10 _± under equal and reproducible gas flow conditions. The dummy silicon carbide semiconductors 11, which act as protective shields, shield the silicon carbide semiconductors 10ι from eddy currents which can occur at the two edge zones of the carrier 16. The dummy silicon carbide semiconductors 11 also act as additional radiation shields.

A silicon carbide semiconductor which has been annealed with a thermal annealing method according to the invention can advantageously be used for the construction of various semiconductor components, preferably of power semiconductor components based on silicon carbide. Examples of such semiconductor components are pn diodes, bipolar transistors, MOSFETs, thyristors, IGBTs or MCTs. Furthermore, the implantation process and the healing process can be carried out in succession in a single system designed for both processes.

Claims

claims

1. A method for the thermal annealing of at least one silicon carbide semiconductor doped by implantation in a gas stream, so that at least one silicon carbide semiconductor (10) is supplied with practically no carbon via the gas stream (12).

2. The method of claim 1, d a d u r c h g e k e n n z e i c h n e t that a gas stream (12) is provided which at least temporarily contains at least one inert gas and / or nitrogen.

3. The method of claim 2, d a d u r c h g e k e n n z e i c h n e t that argon or helium is provided as the inert gas.

4. The method according to any one of the preceding claims, d a - d u r c h g e k e n n z e i c h n e t that a gas stream

(12) is provided which contains hydrogen at least at times.

5. The method according to any one of the preceding claims, d a - d u r c h g e k e n n z e i c h n e t that the gas stream

(12) for doping the at least one silicon carbide semiconductor (10 elements used.

6. The method according to any one of the preceding claims, d a - d u r c h g e k e n n z e i c h n e t that a flow rate of the gas between 0.5 cm / s and 60 cm / s, preferably between 5 cm / s and 25 cm / s is set.

7. The method according to any one of the preceding claims, - characterized in that on the at least one silicon carbide semiconductor (10, a gas atmosphere with a static process pressure between 5000 Pa and 100000 Pa, preferably between 10000 Pa and 50000 Pa.

8. The method according to any one of the preceding claims, characterized in that the at least one silicon carbide semiconductor (10 _± ) is held within a container (13) by means of a carrier (16), the carrier (16) and the container (13 ) at least in the areas that come into contact with the gas stream (12) consist of at least one metal or at least one metal compound.

9. The method according to claim 8, d a d u r c h g e k e n n z e i c h n e t that within the container (13) each have at least one radiation shield (14, 15) based on the

Direction of the gas flow before and after the carrier (16) are provided, the radiation shields (14, 15) at least in the areas that come into contact with the gas flow (12) consist of at least one metal or at least one metal compound.

10. The method according to claim 9, d a d u r c h g ek e n n z e i c h n e t that openings (19) are provided in the radiation shields (14, 15) through which the gas stream (12) passes.

11. The method according to any one of claims 8 to 10, that a metal or a metal compound having a melting point above 1800 ° C is provided.

12. The method according to any one of claims 8 to 11, characterized in that a metal or a metal compound with a vapor pressure less than 10 ^"2 Pa is provided at a temperature of 1800 ° C.

13. The method according to any one of claims 8 to 12, d a d u r c h g e k e n n z e i c h n e t that a hydrogen-resistant metal or a hydrogen-resistant metal compound is provided.

14. The method according to any one of claims 8 to 13, that a metal or metal compound is provided which contains at least one of the elements tantalum, tungsten, molybdenum, niobium, rhenium, osmium, iridium or a carbide of at least one of the elements.

15. The method according to any one of claims 8 to 14, so that the container (13) is preferably heated inductively.

16. The method according to any one of claims 8 to 15, that the gas stream (12) is preheated as it enters the interior of the container.

17. The method according to any one of the preceding claims, characterized in that the at least one silicon carbide semiconductor (10i) is heated to a maximum temperature of at least 1000 ° C at a heating rate of at most 100 ° C / min, preferably of at most 30 ° C / min .

18. The method according to claim 17, so that the maximum temperature is between 1100 ° C and 1800 ° C, preferably between 1400 ° C and 1750 ° C.

19. The method according to claim 17 or claim 18, characterized in that the temperature of the at least one silicon carbide semiconductor (10ι) is kept at the predetermined maximum temperature for a time interval between 2 min and 60 min.

20. The method according to any one of claims 17 to 19, characterized in that the at least one silicon carbide semiconductor (10i) starting from the maximum temperature with a cooling rate of at most 100 ° C / min, preferably of at most 30 ° C / min to an intermediate temperature of is cooled to a maximum of 600 ° C.

21. The method according to any one of claims 17 to 20, - characterized in that the temperature of the at least one silicon carbide semiconductor (10 _± ) is kept at least once at a temperature level during the heating and cooling process.