The present invention relates: to an SiC single crystal, an SiC wafer, and a semiconductor device; more specifically to an SiC single crystal having a highly-linear and highly-oriented basal plane dislocation, and an SiC wafer and a semiconductor device manufactured from such an SiC single crystal.
In SiC (silicon carbide), a high-temperature type (α-type) having a hexagonal crystal structure and a low-temperature type (β-type) having a cubic crystal structure are known. SiC is characterized, in comparison with Si, by having a high thermal resistance, a broad band gap, and a high dielectric breakdown electric field strength. For that reason, a semiconductor including an SiC single crystal is expected as a candidate material of a next-generation power device substituting for an Si semiconductor. In particular, α-type SiC has a band gap broader than β-type SiC and hence the α-type SiC attracts attention as a semiconductor material of an ultralow power-loss power device.
α-type SiC has a {0001} plane (hereunder referred to also as “c-plane”) as the principal crystal plane and a {1-100} plane and a {11-20} plane (hereunder referred to also as “a-plane” collectively) perpendicular to the {0001} plane.
A c-plane growth method has heretofore been known as a method of obtaining an α-type SiC single crystal. The “c-plane growth method” cited here means a method of using as a seed crystal an SiC single crystal in which a c-plane or a plane having an offset angle to the c-plane in a prescribed range is exposed as a growth plane and growing an SiC single crystal over the growth plane by a sublimation reprecipitation method or the like.
The problem has, however, been that, in a single crystal obtained by the c-plane growth method, a large number of defects such as micro pipe defects (tubular voids about several μm to 100 μm in diameter) and threading screw dislocations (hereunder referred to also merely as “screw dislocations”) are generated in the direction parallel to the <0001> direction. Meanwhile, in a c-plane grown crystal, many basal plane dislocations exist in the c-plane and they are complexly intertwined with the screw dislocations in the c-axis direction (Non-patent Literature 1).
In particular, a basal plane dislocation curves largely in a {0001} plane by intertwinement between dislocations. In the case where a basal plane dislocation curves in this way, when a substrate (usually sliced so as to form an offset angle of 4° to 8° to a {0001} plane in order to form an epitaxial film) for manufacturing a device is taken from a single crystal, it sometimes happens that one basal plane dislocation may be exposed at plural sites on the surface of the substrate (refer to
Further, in the case where a basal plane dislocation curves, the basal plane dislocation is oriented to various directions crystallographically. When a device is manufactured with such a single crystal and the device is operated, a stacking fault is formed by the decomposition of the basal plane dislocation into partial dislocations oriented to a crystallographically stable direction (<11-20> direction) during the operation (refer to
A line must not be a straight line in order that the line intersects with a plane at plural sites. It would be better for a line to be rectilinear in order to reduce the number of the intersection sites. Consequently, it is geometrically obvious that it is better to reduce the number density and the total length of a basal plane dislocation and make it rectilinear in order to prevent the basal plane dislocation from being exposed at plural sites on a substrate surface (refer to
Meanwhile, as described in Patent Literature 1, it is possible to reduce a dislocation density in a crystal by using a method (RAF method) in which a c-plane growth is performed after a repeated a-plane growth. Further, in Non-patent Literature 5, it is described that a basal plane dislocation tends to be oriented by the RAF method. In the literature, however, a measure for judging the existence of orientation and linearity is not obvious. Further, a dislocation density is still high, intertwinement with a threading defect occurs frequently. Although the tendency of orientation is recognized partially in each of dislocations, the linearity is not strong and many curved parts exist. Furthermore, such a region is limited to a region of the order of submillimeters.
A problem to be solved by the present invention is to provide an SiC single crystal having a highly-linear basal plane dislocation highly oriented to a stable <11-20> direction, and an SiC wafer and a semiconductor device manufactured from such an SiC single crystal.
In order to solve the above problem, an SiC single crystal according to the present invention has the following configuration:
An SIC wafer according to the present invention includes a wafer cut out in nearly parallel to a {0001} plane from the SiC single crystal according to the present invention.
Further, a semiconductor device according to the present invention includes a device manufactured by using the SiC wafer according to the present invention.
In the case where an SiC single crystal is grown on a c-plane, by using a seed crystal in which the offset angle of a surface satisfies specific conditions, it is possible to obtain the SiC single crystal having a highly-linear basal plane dislocation highly oriented to a stable <11-20> direction.
When a wafer is cut out in nearly parallel to a {0001} plane from such an SiC single crystal, the number of basal plane dislocations exposed on the wafer surface reduces relatively. As a result, even when an SiC single crystal is grown by using such a wafer as a seed crystal or an epitaxial film is formed on the wafer surface, the number of dislocations succeeded by a grown crystal or an epitaxial film also reduces.
Further, when a semiconductor device is manufactured by using such an SiC single crystal, it is possible to suppress the generation of a stacking fault caused by the decomposition of a curved basal plane dislocation during use and the degradation of device characteristics caused by the generation of the stacking fault.
An embodiment according to the present invention is explained hereunder in detail.
[1. SiC Single Crystal]
An SiC single crystal according to the present invention has the following configuration:
An “orientation region” means a region where a basal plane dislocation has a high linearity and is oriented to three crystallographically-equivalent <11-20> directions. Whether or not linearity is high and a basal plane dislocation is highly oriented can be judged by computing an A′ave.(θi)/B.G.(θ1) ratio from an X-ray topography image. The details of the judging method are described later. An SiC single crystal only has to have at least one such orientation region in the interior.
In the case where an SiC single crystal is grown on a c-plane, generally an offset substrate is used for a seed crystal. A c-plane facet as the tip of growth exists at an end of an offset substrate on the upstream side in the offset direction. In order to suppress the generation of heterogeneous polytype, a screw dislocation functioning to take over the polytype of a seed crystal in a growth direction needs to exist in a c-plane facet. As a method for introducing a screw dislocation in a c-plane facet, there is a method of introducing a screw dislocation generation region at an end of a seed crystal on the upstream side in an offset direction, for example.
When a c-plane growth is performed by using such a seed crystal, a deep-colored trace of a c-plane facet (facet mark) caused by a relatively large quantity of trapped nitrogen remains on the upstream side in an offset direction of a grown crystal. Further, a stacking fault and a basal plane dislocation included in a screw dislocation generation region in a seed crystal are taken over by a grown crystal in accordance with growth and flow out toward the downstream side in an offset direction and hence the densities of the screw dislocation and the basal plane dislocation increase. As a result, by an existing c-plane growth method, the basal plane dislocation tends to curve even in a region apart from a facet mark and orientation thereof deteriorates.
In contrast, by using a method described later, it is possible to obtain an SiC single crystal having at least one orientation region existing in a region where a facet mark is excluded. A region where a facet mark exists corresponds to a screw dislocation generation region and hence is intrinsically unsuitable for manufacturing a device. For that reason, it is desirable that an orientation region exists in a region where a facet mark does not exist.
Further, in the case of manufacturing an SiC single crystal by a method described later, when an offset substrate having a c-plane facet at an end is used for a seed crystal, it is possible to obtain an SiC single crystal having at least one orientation region existing nearly in the center of the SiC single crystal. Here, “nearly in the center of an SiC single crystal” means in the vicinity of the center of the surface of a wafer cut out in nearly parallel to a {0001} plane from the SiC single crystal. Since a device is generally formed in a region excluding an end of a wafer, it is desirable that an orientation region exists nearly in the center of a single crystal.
Further, by using a method described later, it is possible to obtain an SiC single crystal having a higher orientation intensity B as a distance from a facet mark increases.
“Having a higher orientation intensity B as a distance from a facet mark increases” means specifically that:
A “distance (L1 or L2) between a facet mark and an orientation region” means a distance between the center of a facet mark appearing on the surface of a wafer and the center of an orientation region when the wafer is cut out in nearly parallel to a {0001} plane from an SiC single crystal. A region where a facet mark exists corresponds to a screw dislocation generation region and hence is intrinsically unsuitable for manufacturing a device. For that reason, it is desirable that an orientation region exists in a region apart from a facet mark. Further, it is possible to improve the orientation and linearity of a basal plane dislocation in one of the <11-20> directions by bringing the <11-20> direction near to the offset direction.
[1.2. Area Ratio of Orientation Region]
The “area ratio of an orientation region (%)” means the proportion of the sum (S) of the areas of orientation regions to the sum (S0) of the areas of measurement regions (=S×100/S0) included in a wafer cut out in nearly parallel to a {0001} plane from an SiC single crystal.
In order to cut out a wafer in nearly parallel to a {0001} plane from an SiC single crystal and manufacture a high-performance semiconductor device at a high yield by using the cut out wafer, it is better for the area ratio of an orientation region to be increased to the largest possible extent. The area ratio of an orientation region is preferably 50% or more, yet preferably 70% or more, and still yet preferably 90% or more.
By using a method described later, it is possible to obtain an SIC single crystal including a relatively large amount of orientation region. Further, by optimizing the manufacturing conditions, it is possible to obtain an SiC single crystal allowing the area ratio of an orientation region of at least one wafer to be 50% or more when one or more wafers are cut out from the SiC single crystal.
[1.3. Orientation Intensity B]
An “orientation intensity B” means the average of three A′ave.(θi)/B.G.(θi) ratios (i=1 to 3) corresponding to three crystallographically-equivalent <1-100> directions. It shows that, as an orientation intensity B increases, a basal plane dislocation has a higher linearity and a higher orientation in the <11-20> direction.
In the case of using a method described later, by optimizing the manufacturing conditions, it is possible to obtain an SiC single crystal including at least one orientation region having an orientation intensity B of 1.2 or more.
In order to cut out a wafer in nearly parallel to a {0001} plane from an SiC single crystal and manufacture a high-performance semiconductor device at a high yield by using the cut out wafer, it is better for the orientation intensity B of an orientation region to be increased to the largest possible extent. An orientation intensity B is preferably 1.3 or more, yet preferably 1.4 or more, and still yet preferably 1.5 or more.
Likewise, it is better for the area ratio of an orientation region having such a high orientation intensity B to be increased to the largest possible extent.
[1.4. Stacking Fault]
“Not including a stacking fault” means that a planarly-projected plane defect region is not included in an X-ray topography image corresponding to {1-100} plane diffraction.
When an SiC single crystal according to the present invention is manufactured by using a method described later, a stacking fault included in a screw dislocation generation region hardly flows out toward the downstream side in the offset direction and hence a stacking fault density immediately after manufacturing is low. Further, simultaneously a basal plane dislocation also hardly flows out, the transformation of an edge of a stacking fault into a screw dislocation does not occur, and hence interaction between dislocations hardly occurs. As a result, a basal plane dislocation is highly oriented, in other words a curved basal plane dislocation reduces, and a stacking fault caused by the decomposition of a curved basal plane dislocation is inhibited from being generated.
[2. Judgment Method of Orientation Region]
An “orientation region” is judged through the following procedures.
[2.1. Processing of Specimen: Procedure (a)]
Firstly, a wafer with the surface nearly parallel to a {0001} plane is cut out from an SiC single crystal.
In the present invention, the procedure is based on the premise that general processing of a specimen for imaging a basal plane dislocation ({0001} in-plane dislocation) by X-ray topography is applied. Specifically, processing is applied under the following conditions.
That is, a wafer having an offset angle of 10° or less is cut out by slicing an SiC single crystal in nearly parallel to a {0001} plane. A wafer having a thickness suitable for X-ray topography measurement is produced by grinding and polishing and thus flattening the wafer surface and further removing a damaged layer on the surface. CMP treatment is preferably used for removing a damaged layer.
If a wafer is too thin, a measured region is localized in the thickness direction, resultantly an average dislocation structure in a crystal cannot be evaluated, and the measured value of an orientation intensity tends to vary. If a wafer is too thick in contrast, X-rays hardly transmit. Consequently, the thickness of a wafer is preferably 100 to 1,000 μm, yet preferably 500±200 μm, and still yet preferably 500±100 μm.
[2.2. X-Ray Topography: Procedure (b)]
Successively, X-ray topography measurement by transmission arrangement is applied to the wafer and X-ray topography images corresponding to three crystallographically-equivalent {1-100} plane diffractions are photographed.
In the present invention, the procedure is based on the premise that the measurement is carried out under ordinary X-ray topography measurement conditions for detecting a basal plane dislocation image. Specifically, the measurement is applied under the following conditions:
A Lang method (transmission arrangement topography) is a means to be able to: photograph a defect distribution of a whole wafer; and be used for the quality inspection of a wafer. In the Lang method, there are a method of using large-scale synchrotron radiation facility and a method of using a small-scale X-ray generator of a laboratory level. The measurement described in the present invention can be carried out by either of the methods. A general technique applied to latter method is explained here.
As shown in
An X-ray tube having Mo as the anode is used as the X-ray source 22 and the diffraction conditions are tailored to the wavelength of Kα1 in the Kα rays of characteristic X-rays. A second slit 28 has the functions of blocking primary X-rays coming through the specimen 26, appropriately narrowing the width so as to let only diffracted X-rays through, and reducing backgrounds caused by scattered X-rays. A film (or nuclear emulsion plate) 30 is arranged on the rear side of the second slit 28 and an X-ray detector 32 is arranged further on the rear side thereof.
With the arrangement, by scanning the specimen 26 in parallel to the specimen plane together with the film 30, a diffraction image ranging over the whole specimen 26 can be obtained.
A topograph thus obtained is called a traverse topograph. The topograph may sometimes be called a projection topograph because a three-dimensional defect image is projected two-dimensionally.
As a method for detecting a dislocation having a Burgers vector in a {0001} in-plane direction, generally {11-20} plane diffraction is also used. By the {11-20} plane diffraction, however, a stacking fault in a {0001} plane cannot be detected.
Meanwhile, whereas a dislocation having Burgers vectors of the three principal axes directions in a {0001} plane can be detected even in one measurement plane by the {11-20} plane diffraction, only a dislocation having Burgers vectors of two principal axes directions in the three principal axes directions is detected in one measurement plane by {1-100} plane diffraction.
In the present invention therefore, {1-100} plane diffraction capable of detecting also a stacking fault is used and the measurement is applied to three crystallographically-equivalent crystal planes having different angles.
[2.3. Digitization and Image Preprocessing of Topography Image: Procedure (c)]
Successively, each of the three X-ray topography images is transformed into a digital image obtained by quantifying the brightness of each point in the image and each of the three digital images is comparted into a measurement region having a size of 10±0.1 mm.
In the present invention, the procedure is based on the premise that general image processing for carrying out image analysis is applied. Specifically, digitization and image preprocessing are carried out under the following conditions.
Successively, two-dimensional Fourier transform processing is applied to each of the three digital images in the measurement region corresponding to an identical region on a wafer and a power spectrum (spectrum of the amplitude A of a Fourier coefficient) is obtained.
The principle of image analysis by two-dimensional Fourier transform is described in detail in the following literatures for example;
Successively, each of the three power spectra is converted into a polar coordinate function and a function Aave.(θ) of angle (direction) dependency of an average amplitude A is obtained (0°≦θ≦180°) (procedure (e)). In the conversion into a polar coordinate function, the following processing is applied. In a power spectrum, an average amplitude A at an angle θ in the counterclockwise direction from 0° of the x-axis direction is computed. That is, θ is equally divided in the range of 0° to 180° and the average of the amplitudes of Fourier coefficients from the center to the end of a power spectrum is obtained at each angle.
Successively, an integrated value A′ave.(θ) of the three Aave.(θ)'s is shown in a graph (x-axis: θ, y-axis: A′ave. ) and the ratio of a peak value A′ave.(θi) to a background B.G.(θi) (=A′ave.(θi)/B.G.(θi) ratio) is computed at each of three θi's (i=1 to 3) corresponding to the three <1-100> directions (procedure (f)). When all of the three A′ave.(θi)/B.G.(θi) ratios thus obtained are 1.1 or more, the region of the wafer corresponding to the three measurement regions is judged as an “orientation region” (procedure (g)).
In the graph of an integrated value A′ave.(θ), the ratio of a peak value A′ave.(θi) to a background B.G.(θi) (=A′ave.(θi)/B.G.(θi) ratio) is computed for each of the three θi's (i=1 to 3) corresponding to the <1-100> directions.
A “background B.G.(θi)” means the distance from the x-axis to a background line at the position of θi. A “background line” means a tangent line touching the bottom end of the graph of the integrated value A′ave.(θ) in the vicinity of θi (refer to
When a clear peak is shown at each of the three θi's (i=1 to 3) corresponding to the <1-100> directions by applying appropriate image processing, the region on the wafer corresponding to the measurement regions is judged as an “orientation region”. A “clear peak” means that an A′ave.(θi)/B.G.(θi) ratio (i=1 to 3) is 1.1 or more.
In Fourier transform, a peak appears in a direction perpendicular to an actual orientation direction. In a crystal structure of a hexagonal system such as SiC, the direction perpendicular to the <11-20> direction is the <1-100> direction (
[2.6. Detailed Explanation of Two-dimensional Fourier Transform]
A wave such as an acoustic wave, an electromagnetic wave, or a seismic wave can be expressed by the combination of trigonometric waves (sin, cos) having different magnitudes (amplitudes), frequencies, and phases. Likewise, as shown in
The Fourier transform of an acoustic wave or the like is to obtain a Fourier coefficient containing the information of the phase and the amplitude of a trigonometric wave having a certain frequency. Likewise, the Fourier transform of an image is, when the image is converted to a function of brightness in two-dimensional coordinates, to obtain
Fourier transform F(kx, ky) of an image f(x, y) having a size of N×N pixels is represented by the following expression (1). Here, f is the brightness at a coordinate (x, y) and can be obtained by representing a digital image by a bitmap and taking out the information of the brightness at each point from the image data. k is a frequency.
A Fourier coefficient F(kx, ky) calculated by the expression (1) is generally a complex number and is represented as a point of F(kx, ky)=a+ib on a complex plane. On a complex plane, an angle formed between a line connecting an origin to a+ib and the real number axis means the phase of the trigonometric function of the frequency having a cycle from the center of an image to the direction of a coordinate (x, y). √(a2+b2) that is the distance from the origin to a+ib represents the amplitude A of the trigonometric function wave.
A power spectrum (
For example, when two-dimensional Fourier transform is applied to an image of regularly-arrayed particles or the like and a power spectrum is obtained, a clear spot appears and the contribution of a specific frequency in a specific periodicity direction can be detected remarkably. Meanwhile, two-dimensional Fourier transform can apply not only to an image having regularity but also to the investigation of orientation of a fiber. Further, it can apply to the investigation of the direction and the intensity in the orientation of not only a fiber but also all images allowing the direction and the flow to be observed (Reference Literatures 1 to 3). In such a power spectrum, not a clear spot at a distance from a center but a fuzzy intensity distribution anisotropically and unevenly distributed from the center of the spectrum is observed. When the orientation of a fiber in an image is small, an isotropic power spectrum is obtained. In contrast, when the uniaxial orientation is strong, an ellipse or a peak largely flattening in a direction perpendicular to an orientation direction appears in a power spectrum.
Here, an amplitude A of a power spectrum at each coordinate is represented by a function A(θ, r) of polar coordinates (
With regard to a certain angle θ, A (θ, r)'s are averaged for all of the distance r's, and the θ dependency Aave.(θ) of the average amplitude is obtained. On the occasion, θ is in the range of 0° to 180°. This is because 180° to 360° has a nature to be identical to 0° to 180°. Specifically, after the two-dimensional Fourier transform, the angle of 0° to 180° is equally divided, the amplitude A (r cos θ, r sin θ) of a Fourier coefficient located at a distance r is obtained with regard to each angle θ, and an average value Aave.(θ) is obtained with regard to r. This is expressed by the expression (2).
As described above, when a largely-flattening ellipse or a peak appears in a power spectrum, Aave.(θ) comes to be a maximum value or shows a steep peak at a specific θ. θ at which such a maximum value or a steep peak appears is θ in a direction perpendicular to the orientation direction in an image before Fourier transform.
As a method for obtaining the intensity of orientation, there is also a method of drawing Aave.(θ) as a polar coordinate graph, approximating a curve by an ellipse and obtaining a long axis/short axis ratio (Reference Literatures 1 to 3). In the Fourier transform of a basal plane dislocation image obtained in the present invention however, Aave.(θ) shows a relatively sharp maximum value and is not uniaxial orientation and hence ellipse approximation that is applicable in the case of ordinary fiber orientation cannot be applied.
In the present invention therefore, with regard to Aave.(θ) obtained by two-dimensional Fourier transform, the orientation of a basal plane dislocation is evaluated by following specific procedures as shown below:
In the present invention, in order to apply Fourier transform to a basal plane dislocation image, Fiber Orientation Analysis Ver. 8.13 developed by the authors of Reference Literatures 1 to 3 is used. The Fourier transform software carries out the treatment of taking out information of the brightness of each point from image data, applying Fourier transform processing, and obtaining a power spectrum and Aave.(θ). Detailed procedures are described in Reference Literatures 1 to 3 and Reference URL 1. In order to apply Fourier transform processing to an image with the software, the image is converted to a bitmap beforehand in order to take out the numerical information of brightness. In order to further apply fast Fourier transform, the number of pixels at one side of an image is adjusted beforehand so as to be an integral multiple of four.
Fourier transform processing is decided uniquely and hence any software may be used as long as the software can carry out the same processing. The specific feature of the present software developed for evaluating orientation however is to be able to obtain Aave.(θ). When Aave.(θ) cannot be obtained automatically with other software, it is necessary to use a power spectrum obtained by mapping brightness on (x, y) coordinates and apply the same calculation in accordance with the expression (2).
[3. Manufacturing Method of SiC Single Crystal]
An SIC single crystal according to the present invention can be manufactured by various methods and for example can be manufactured by using an SIC seed crystal satisfying the following conditions and growing a new crystal on the surface of the SiC seed crystal:
Here, a “principal growth plane” means a plane that constitutes a part of exposed planes of an SIC seed crystal and has a component of a crucible center axis/raw material direction in its normal vector ‘a’. A “crucible center axis/raw material direction” in a sublimation precipitation method is a direction from an SiC seed crystal toward a raw material and a direction parallel to the center axis of a crucible. In other words, a “crucible center axis/raw material direction” represents a macro growth direction of an SiC single crystal and generally means a direction perpendicular to the bottom plane of an SiC seed crystal or a surface of a seed crystal pedestal to fix the SiC seed crystal.
An “sub-growth plane” means an individual plane constituting a principal growth plane. An sub-growth plane may be either a flat plane or a curved plane.
An “offset angle θ” means an angle formed by a normal vector ‘a’ of an sub-growth plane and a normal vector ‘p’ of a {0001} plane of an SiC seed crystal.
A “{0001} plane inclination angle β” means an angle formed by a vector ‘q’ of a crucible center axis/raw material direction and a normal vector ‘p’ of a {0001} plane of an SiC seed crystal.
An “sub-growth plane inclination angle α” means an angle formed by a vector ‘q’ of a crucible center axis/raw material direction and a normal vector ‘a’ of an sub-growth plane.
An “downstream side in the offset direction” means a side in a direction opposite to the direction of the tip of a vector ‘b’ formed by projecting a normal vector ‘p’ of a {0001} plane on an sub-growth plane.
In
The {0001} plane uppermost part is the point X3. The sub-growth plane inclination angle α1 of the X3X4 plane is in the relation of α1≦β. Further, the sub-growth plane inclination angle α2 of the X4X5 plane is zero. The point X5 is a point having the longest distance from the point X3 and also is the {0001} plane lowermost part in the principal growth plane outer periphery.
With regard to the X1X2 plane and the X5X6 plane, the normal vectors thereof are perpendicular to the vector ‘g’, respectively. Further, the X1X6 plane is a plane touching a crucible or a seed crystal pedestal (not shown in the figure). Consequently, the principal growth plane includes the X2X3 plane, the X3X4 plane, and the X4X5 plane. Furthermore, the direction from the point X3 of the {0001} plane uppermost part toward the point X5 at the principal growth plane outer periphery is a direction (principal direction) having a plurality of sub-growth planes. In the sub-growth planes existing along the principal direction, the sub-growth plane including the {0001} plane uppermost part is the X3X4 plane and the plane is the first sub-growth plane. The second sub-growth plane is the X4X5 plane and has the relation of θ1<θ2.
The SIC seed crystal 12b scarcely includes a screw dislocation. An SiC single crystal not including a screw dislocation, as described in Patent Literature 1 for example, is obtained by growing on a seed crystal having a growth plane nearly perpendicular to a {0001} plane. Consequently, on the surfaces of the X2X3 plane and the X3X4 plane, a screw dislocation generation region (represented with the heavy line in
The screw dislocation generation region is formed by the following methods:
As shown in
That is, when the offset angle θ1 of a first sub-growth plane (X3X4 plane) is reduced relatively, a screw dislocation exposed on the first sub-growth plane or in the vicinity thereof in a seed crystal is succeeded nearly by a grown crystal. As a result, it is possible to surely supply a screw dislocation in a c-plane facet existing on the first sub-growth plane or in the vicinity thereof and thereby a heterogeneous polytype and a differently oriented crystal can be inhibited from being generated in the grown crystal. By further reducing the offset angle θ1, it is possible to nearly completely inhibit a screw dislocation and a basal plane edge dislocation from leaking to the downstream side in the offset direction in the grown crystal.
In contrast, when the offset angle θ2 of a second sub-growth plane (X4X5 plane) increases relatively, the probability that a screw dislocation in a seed crystal exposed on the second sub-growth plane is succeeded by a grown crystal as it is reduces and the screw dislocation is likely to be transformed into a basal plane edge dislocation. A basal plane edge dislocation has a nature of being likely to flow as it is toward the downstream side (point X5 side) in the offset direction. As a result, it is possible to reduce the screw dislocation density in the grown crystal on the second sub-growth plane. Further, a new screw dislocation is likely to be inhibited from being generated.
In an SiC seed crystal 12b further, inclined planes X2X3 and X3X4 are formed so that a {0001} plane uppermost part X3 may be inside a principal growth plane. When a crystal is grown by using it therefore, as shown in
Further, when an SiC seed crystal 12b of such a shape is cut out from a single crystal grown by using a plane nearly perpendicular to a c-plane as a growth plane and an SiC single crystal is grown by using it, a basal plane dislocation remaining in a grown crystal is likely to be oriented to the <11-20> direction. Further, it is possible to obtain an SiC single crystal including a region not substantially including a stacking fault. This is presumably because, a dislocation coming to be an origin of a basal plane dislocation and a screw dislocation transforming into a stacking fault are few in the seed crystal itself, a screw dislocation scarcely leaks from a screw dislocation generation region formed at a seed crystal end, and the intertwinement of a basal plane dislocation and a screw dislocation does not occur.
[4. SiC Wafer]
An SiC wafer according to the present invention includes a wafer cut out in nearly parallel to a {0001} plane from an SiC single crystal according to the present invention.
The surface of a wafer is not necessarily completely parallel to a {0001} plane and may incline from a {0001} plane to some extent. The allowable degree of inclination (offset angle) varies in accordance with the application of a wafer but usually about 0° to 10°.
An obtained wafer is used for various applications as it is or in the state of forming a thin film on a surface. When a semiconductor device is manufactured by using a wafer for example, an epitaxial film is formed on a wafer surface. As an epitaxial film, specifically SiC, nitride such as GaN, or the like is used.
[5. Semiconductor Device]
A semiconductor device according to the present invention includes a device manufactured by using an SiC wafer according to the present invention. As a semiconductor device, specifically there is
In the case where an SiC single crystal is grown on a c-plane, by using a seed crystal in which the offset angle of a surface satisfies specific conditions, it is possible to obtain the SiC single crystal having a highly-linear basal plane dislocation highly oriented to a stable <11-20> direction.
When a wafer is cut out in nearly parallel to a {0001} plane from such an SiC single crystal, the number of basal plane dislocations exposed on a wafer surface reduces relatively. As a result, even when an SiC single crystal is grown by using such a wafer as a seed crystal or an epitaxial film is formed on a wafer surface, the number of dislocations succeeded by a grown crystal or an epitaxial film also reduces.
Further, when a semiconductor device is manufactured by using such an SiC single crystal, it is possible to suppress the generation of a stacking fault caused by the decomposition of a curved basal plane dislocation during use and the degradation of device characteristics caused by the generation of the stacking fault.
[1. Preparation of Specimen]
A step of growing an SiC single crystal on a growth plane nearly perpendicular to a c-plane, a step of taking out a seed crystal having a growth plane nearly perpendicular to both the last growth plane and the c-plane from the obtained SiC single crystal, and a step of growing an SiC single crystal again by using the seed crystal were repeated. A c-plane offset substrate was taken out from the obtained SiC single crystal and processed to the shape shown in
[2. Test Method]
[2.1. X-Ray Topography Measurement]
With regard to the three planes of a (−1010) plane, a (1-100) plane, and a (01-10) plane, those being crystallographically equivalent and having different plane orientations forming angles of 60° with each other, {1-100} plane diffraction images were measured and X-ray topography images were obtained on photosensitive films. In the obtained three X-ray topography images, basal plane dislocation images rectilinearly extending in the {0001} plane were observed.
The measurement conditions of the X-ray topography are as follows:
The X-ray topography images were read with a scanner and thereby digitized. The scanning condition was a gray scale and the resolution was about 1,000 pixels/cm. A square measurement region where the length L of each side is 10 to 20 mm was taken out from the vicinity of the center of each of the digitized X-ray topography images. The gray level was corrected so that a basal plane dislocation site may be darkest and a non-dislocation site may be brightest. The resolution of an image was dropped so that the number of the pixels on one side of the image may be 512 pixels and the image was transformed into an image file of a bitmap format.
[2.3. Orientation Measurement by Fourier Transform]
The preprocessed three digital images were processed by Fiber Orientation Analysis Ver. 8.13 as Fourier transform software and a power spectrum and an Aave.(θ) were obtained for each of the three digital images. Further, the Aave.(θ)'s obtained for the three images were integrated. Further, by using the integrated value A′ave.(θ), A′ave.(θi)/B.G.(θi) ratios at three θi's (i=1 to 3) corresponding to the <1-100> direction and an orientation intensity B were obtained.
[3. Result]
From
Similar treatment was applied to a 12-mm square region, a 14-mm square region, a 16-mm square region, an 18-mm square region, and a 20-mm square region and integrated values A′ave.(θ)'s were obtained, respectively. From each of the obtained integrated values A′ave.(θ)'s, A′ave.(θi)/B.G.(θi) ratios at three θi's (i=1 to 3) corresponding to the <1-100> direction and an orientation intensity B were obtained. The results are shown in Table 1.
In the case of Example 1, regardless of the size of the measurement region, clear peaks are shown at the three θi's corresponding to the <1-100> direction. Further, as the measurement region increases, the A′ave.(θi)/B.G.(θi) ratios decrease. This is because a basal plane dislocation comes to be relatively unclear when a measurement region increases.
An X-ray topography image was divided into a plurality of 10-mm square regions and the orientation intensities were obtained likewise. As a result, high orientation intensities of 1.5 or more are obtained in the area ratios of 90% or more including the center region. In contrast, an orientation intensity in a screw dislocation generation region shows a low value.
[1. Preparation of Specimen]
A step of growing an SiC single crystal on a growth plane nearly perpendicular to a c-plane, a step of taking out a seed crystal having a growth plane nearly perpendicular to both the last growth plane and the c-plane from the obtained SiC single crystal, and a step of growing an SiC single crystal again by using the seed crystal were repeated. A c-plane offset substrate was taken out from the obtained SiC single crystal. Here, such processing as shown in
[2. Test Method]
Following the same procedures as Example 1, A′ave.(θi)/B.G.(θi) ratios at three θi's corresponding to the <1-100> direction and an orientation intensity B were obtained.
[3. Result]
The integrated value A′ave.(θ) shows peaks at two θi's of the [−1100] direction and the [0-110] direction in three θi's (i=1 to 3) corresponding to the <1-100> direction. The A′ave.(θi)/B.G.(θi) ratios, however, are relatively small. Further, a clear peak is not shown at θi corresponding to the [−1010] direction. A′ave.(θi)/B.G.(θi) ratio is 1.18 at θi corresponding to the [−1100] direction. A′ave.(θi)/B.G.(θi) ratio is 1.03 at θi corresponding to the [−1010] direction. Further, A′ave.(θi)/B.G.(θi) ratio is 1.27 at θi corresponding to the [0-110] direction. From the results, it is found that the orientation of a basal plane dislocation in the <11-20> direction is low. Further, the orientation strength B that is the average thereof is 1.16.
Similar processing was applied to a 12-mm square region, a 14-mm square region, a 16-mm square region, an 18-mm square region, and a 20-mm square region and integrated value A′ave.(θ)'s were obtained, respectively. From each of the obtained integrated values A′ave.(θ)'s, A′ave.(θi)/B.G.(θi) ratios at three θi's corresponding to the <1-100> direction and an orientation intensity B were obtained. The results are shown in Table 2.
In the case of Comparative Example 1, regardless of the size of the measurement region, no clear peak is shown at least one θi in the three θi's corresponding to the <1-100> direction. Further, as the measurement region increases, the A′ave.(θi)/B.G.(θi) ratios decrease. As a matter of course, the orientation intensity in another partition region is smaller than those when they are compared by standardizing the size of the measurement regions.
Although the embodiments according to the present invention have heretofore been explained in detail, the present invention is not limited at all by the embodiments and can be modified variously within the range not deviating from the gist of the present invention.
An SiC single crystal according to the present invention can be used as a semiconductor material of an ultralow power-loss power device.
Number | Date | Country | Kind |
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2011-109773 | May 2011 | JP | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/JP2012/062448 | 5/16/2012 | WO | 00 | 10/8/2013 |
Publishing Document | Publishing Date | Country | Kind |
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WO2012/157654 | 11/22/2012 | WO | A |
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20110006309 | Momose et al. | Jan 2011 | A1 |
20110024766 | Jenny et al. | Feb 2011 | A1 |
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20140027787 | Gunjishima et al. | Jan 2014 | A1 |
Number | Date | Country |
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10 2010 029 755 | Dec 2011 | DE |
H10-45499 | Feb 1998 | JP |
A-2003-119097 | Apr 2003 | JP |
A-2004-323348 | Nov 2004 | JP |
A-2006-225232 | Aug 2006 | JP |
A-2010-235390 | Oct 2010 | JP |
A-2012-046377 | Mar 2012 | JP |
A-2012-072034 | Apr 2012 | JP |
A-2012-116676 | Jun 2012 | JP |
2012157654 | Nov 2012 | WO |
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Number | Date | Country | |
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20140027787 A1 | Jan 2014 | US |