The present invention relates to a method of epitaxially depositing a silicon carbide layer on a sapphire substrate, and a structure obtained by the same.
Alpha silicon carbide has a hexagonal crystal structure, and beta silicon carbide has a cubic crystal structure of zinc blende type.
Silicon carbide substrates having a (0001) surface orientation are not commercially available at a diameter greater than 4 (or 5) inches at the present time. Such unavailability of silicon carbide (SiC) substrates currently makes it impossible to provide a 200 mm substrate or a 300 mm substrate containing a silicon carbide layer. Thus, formation of a single-crystalline silicon carbide layer on a substrate having a diameter of six inches or greater depends on the ability to deposit single crystalline silicon carbide material on a non-SiC single crystalline substrate by epitaxy.
In order to form a structure, such as a graphene layer, derived from a layer of silicon carbide on a substrate having a diameter of six inches or greater, the formation of a single crystalline silicon carbide material by heteroepitaxial growth on a large substrate is necessary. Graphene is a structure consisting of carbon as a two-dimensional sheet. Moreover, “graphene” as used herein denotes a one-atom thick planar sheet of sp2-bonded carbon atoms that are densely packed in a honeycomb crystal lattice. Graphene can be comprised of single-layer graphene (nominally 0.34 nm thick), few-layer graphene (2-10 graphene layers), multi-layer graphene (greater than 10 graphene layers), a mixture of single-layer, few layer, and multi-layer graphene, or any combination of graphene layers mixed with amorphous carbon (a-C) and/or disordered carbon phases. A disordered carbon phase may be, for example, a crystalline carbon phase with a high density of defects or a nanocrystalline carbon material.
Further, graphene provides excellent in-plane electrical conductivity and carrier mobility. Semiconductor devices employing graphene have been suggested in the art to provide high-density and high-switching-speed semiconductor circuits. Carbon atoms are arranged in a two-dimensional honeycomb crystal lattice in which each carbon-carbon bond has a length of about 0.142 nm. It is possible by using a similar heteroepitaxial growth method that a graphene layer may be grown by direct epitaxial deposition of carbon atoms on, i.e., addition of carbon atoms onto the surface of, a surface of a single crystalline silicon carbide (SiC) layer.
Single crystalline and/or polycrystalline silicon carbide material is grown on a single crystalline sapphire substrate in an ultrahigh vacuum environment. The sapphire substrate is pretreated to remove impurities from an exposed surface in the ultrahigh vacuum environment. A high quality single crystalline or polycrystalline silicon carbide film can be grown directly on the sapphire substrate by chemical vapor deposition employing a silicon-containing reactant and a carbon-containing reactant. Formation of single crystalline silicon carbide has been verified by x-ray diffraction, secondary ion mass spectroscopy, and transmission electron microscopy.
According to an aspect of the present invention, a method of forming a semiconductor-carbon alloy layer on a sapphire substrate is provided. The method includes: placing a sapphire substrate in a vacuum environment; and providing a semiconductor-containing precursor and a carbon-containing precursor into the vacuum environment, wherein a single crystalline or polycrystalline semiconductor-carbon alloy layer is epitaxially formed directly on a crystallographic surface of the sapphire substrate.
According to another aspect of the present invention, a structure is provided, which includes a single crystalline or polycrystalline semiconductor-carbon alloy layer located directly on a crystallographic surface of a sapphire substrate.
As stated above, the present invention relates to a method of epitaxially depositing a silicon carbide layer on a sapphire substrate, and a structure obtained by the same, which are now described in detail with accompanying figures. It is noted that like and corresponding elements are referred to by like reference numerals. The drawings are not in scale. In drawings including a coordinate system, the x-axis is along a horizontal direction within the plane of the drawing, the y-axis is along a direction perpendicular to the plane of the drawing, and the z-axis is along a vertical direction within the plane of the drawing.
As used herein, an “ultrahigh vacuum” environment refers to a vacuum environment having a pressure less than 1.0×10−6 Ton.
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It is noted that, by reducing the deposition temperature or by otherwise providing inferior growth conditions, for example, by providing an ambient including a significant level of residual gases within a deposition chamber, the single crystalline semiconductor-carbon alloy layer 120 can be replaced with a polycrystalline semiconductor-carbon alloy layer including at least one polycrystalline semiconductor-carbon alloy portions each having a hexagonal crystal structure and a (0001) surface orientation and epitaxially deposited on a (0001) surface of the sapphire substrate 110, while including grain boundaries between the various grains.
The sapphire substrate 110 consists essentially of aluminum oxide, i.e., Al2O3, and may include trace amounts of impurities at concentrations that do not affect the crystal structure of the sapphire substrate 110. The entirety of the sapphire substrate 110 is single crystalline. Sapphire substrates are currently commercially available at diameters up to 8 inches. The surface orientation of the sapphire substrate 110 is a (0001) orientation. The plane of the (0001) orientation is also referred to as a C plane.
The single crystalline semiconductor-carbon alloy layer 120 is a single crystalline layer in which all atoms are epitaxially aligned to all other atoms of the single crystalline semiconductor-carbon alloy layer 120 except for naturally present imperfections in the crystal lattice structure such as dislocations and/or point defects. Point defects can be substitutional defects or interstitial defects as known in the art.
The single crystalline semiconductor-carbon alloy layer 120 can be replaced with a polycrystalline semiconductor-carbon alloy layer including at least one polycrystalline semiconductor-carbon alloy portions. In the case of highly textured polycrystalline materials, high angle grain boundaries are typically observed.
In a first illustrative example, the single crystalline semiconductor-carbon alloy layer 120 can be a layer of a silicon-carbon alloy. Carbon has an atomic concentration from 20% to 75% in the silicon-carbon alloy, and preferably has an atomic composition from 45% to 55% in the silicon-carbon alloy. Alternately, a polycrystalline semiconductor-carbon alloy layer that is a layer of polycrystalline silicon-carbon alloy portions can be formed instead of the single crystalline semiconductor-carbon alloy layer 120.
In a second illustrative example, the single crystalline semiconductor-carbon alloy layer 120 can be a layer of a silicon-germanium-carbon alloy. Carbon has an atomic concentration from 20% to 75% in the silicon-germanium-carbon alloy, and preferably has an atomic composition from 45% to 55% in the silicon-germanium-carbon alloy. Alternately, a polycrystalline semiconductor-carbon alloy layer that is a layer of polycrystalline silicon-germanium-carbon alloy portions can be formed instead of the single crystalline semiconductor-carbon alloy layer 120.
In a third illustrative example, the single crystalline semiconductor-carbon alloy layer 120 can be a layer of a germanium-carbon alloy. Carbon has an atomic concentration from 20% to 75% in the germanium-carbon alloy, and preferably has an atomic composition from 45% to 55 in the germanium-carbon alloy. Alternately, a polycrystalline semiconductor-carbon alloy layer that is a layer of polycrystalline germanium-carbon alloy portions can be formed instead of the single crystalline semiconductor-carbon alloy layer 120.
In a fourth illustrative example, the single crystalline semiconductor-carbon alloy layer 120 can be a superlattice including multiple repetitions of a first material layer and a second material layer. At least one of the first material layer and a second material layer includes carbon, and at least one of the first material layer and a second material layer includes at least one of silicon and germanium. The first material layer may include silicon, germanium, or an alloy of silicon and the second material layer may include carbon or a carbon alloy. An exemplary combination of the first material layer and the second material layer is a silicon layer and a carbon layer. Another exemplary combination of the first material layer is a silicon boride layer and a carbon layer. Alternately, a polycrystalline semiconductor-carbon alloy layer that includes multiple repetitions of the first material layer and the second material layer can be formed instead of the single crystalline semiconductor-carbon alloy layer 120.
The single crystalline semiconductor-carbon alloy layer 120 is epitaxially deposited on the top surface of the sapphire substrate 110. Because the top surface of the sapphire substrate 110 has a hexagonal symmetry, which is the symmetry of the (0001) surface of a hexagonal crystal structure, the single crystalline semiconductor-carbon alloy layer 120 is formed with the same hexagonal crystal symmetry with a (0001) surface orientation, which also has a hexagonal symmetry, i.e., is invariant under rotation by 60 degrees along the z-axis that is perpendicular to the interface between the sapphire substrate 110 and the single crystalline semiconductor-carbon alloy layer 120. The single crystalline semiconductor-carbon alloy layer 120 can be a single crystalline semiconductor carbide layer such as a single crystalline silicon carbide layer. In this case, the single crystalline silicon carbide layer has alpha phase that has hexagonal crystal structure in which the surface orientation, i.e., the orientation of the x-y plane, is a (0001) orientation.
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The sapphire substrate 210 consists essentially of aluminum oxide as in the first embodiment. The entirety of the sapphire substrate 210 is single crystalline. However, the surface orientation of the sapphire substrate 210 is a (1102) orientation. The plane of the (1102) orientation is also referred to as an R plane.
The single crystalline semiconductor-carbon alloy layer 220 is a single crystalline layer in which all atoms are epitaxially aligned to all other atoms of the single crystalline semiconductor-carbon alloy layer 220 except for naturally present imperfections in the crystal lattice structure such as dislocations and/or point defects. Point defects can be substitutional defects or interstitial defects as known in the art. The composition of the single crystalline semiconductor-carbon alloy layer 220 can vary in the same manner as in the first embodiment.
The single crystalline semiconductor-carbon alloy layer 220 is epitaxially deposited on the top surface of the sapphire substrate 210. The top surface of the sapphire substrate 210 has a cubic symmetry, which is the symmetry of the (1102) surface of a hexagonal crystal structure. The single crystalline semiconductor-carbon alloy layer 220 is formed with cubic crystal symmetry with a (110) surface orientation, which has a rectangular symmetry, i.e., is invariant under rotation by 180 degrees along the z-axis that is perpendicular to the interface between the sapphire substrate 210 and the single crystalline semiconductor-carbon alloy layer 220. The single crystalline semiconductor-carbon alloy layer 220 can be a single crystalline semiconductor carbide layer such as a single crystalline silicon carbide layer. In this case, the single crystalline silicon carbide layer has beta phase that has cubic crystal structure of zinc blende type. The surface orientation, i.e., the orientation of the x-y plane, of the single crystalline semiconductor-carbon alloy layer 220 is a (110) orientation.
Single crystalline sapphire substrates of different crystallographic orientations are employed to form the first and second exemplary structures. To form the first exemplary structure, a single crystalline sapphire substrate having a (0001) surface orientation can be employed. To form the second exemplary structure, a single crystalline sapphire substrate having a (1102) surface orientation can be employed. The processing methods employed to form the first and second exemplary structures can be the same. Because identical processing steps can be employed for the first and second exemplary structures, each of the single crystalline sapphire substrate having a (0001) surface orientation and the single crystalline sapphire substrate having a (1102) surface orientation are herein referred to as a single crystalline sapphire substrate. The first exemplary structure can be eventually formed on the single crystalline sapphire substrate having a (0001) surface orientation, and the second exemplary structure can be eventually formed on the single crystalline sapphire substrate having a (1102) surface. The common processing steps are described below.
First, appropriate analysis can be performed before deposition of silicon carbide as needed on each single crystalline sapphire substrate, be it the single crystalline sapphire substrate having a (0001) surface orientation or the single crystalline sapphire substrate having a (1102) surface. For example, x-ray data on the sapphire substrates alone can be generated before any deposition on a single crystalline sapphire substrate. Subsequently, each sapphire substrate can be cleaned by chemical methods. Each single crystalline sapphire substrate can be cleaned employing a SC1 clean process in a solution including H2O2, NH4OH, and H2O. Thereafter, each single crystalline sapphire substrate can be cleaned employing a SC2 clean process in a solution including H2O2, HCl, and H2O. The surface of each single crystalline sapphire substrate can be treated with dilute hydrofluoric acid to form a hydrogen-terminated surface. Isopropyl alcohol and/or nitrogen gas can be employed to dry the hydrogen-terminated surface without affecting the hydrogen-termination. Any equivalent surface clean that removes impurities from the surface of the sapphire substrate can also be employed.
The sapphire substrate can be subsequently placed in a vacuum environment. Specifically, after formation of the hydrogen-terminated surface, the sapphire substrate can be loaded in a process chamber, which can be then pumped down to a base pressure less than 5.0×10−8 Ton. Generally, the vacuum environment can be provided by an ultrahigh vacuum chamber having a base pressure less than 1.0×10−6 Ton. Each sapphire substrate can be then transferred to a process chamber, which can be maintained at a base pressure less than 2.0×10−8 Ton. While the transfer can be typically effected, for example, at a temperature from 300° C. to 800° C., the transfer can be effected at any operating temperature of the process chamber provided mechanical assemblies support a transfer at such a temperature.
The process chamber can be filled with hydrogen gas at a purge pressure, which can be, for example, between 0.1 mTorr to 100 mTorr, and typically from 1 mTorr to 10 mTorr. The temperature of the process chamber can be ramped to a deposition temperature, at which a subsequent deposition process is to be performed. Any other temperature ramp rate may be employed provided that the process chamber is capable of withstanding the rate of change in temperature without mechanical problems (such as component breakage). Any equivalent thermal surface clean can also be employed.
A semiconductor-containing precursor and a carbon-containing precursor can be provided into the vacuum environment so that a single crystalline semiconductor-carbon alloy layer is epitaxially formed directly on the crystallographic surface of the sapphire substrate. Specifically, after the hydrogen gas is shut off, the silicon-containing reactant gas and the carbon-containing reactant gas are flown into the process chamber simultaneously. The temperature of the process chamber can be maintained at a predetermined processing temperature, or can be ramped as needed to facilitate deposition. In general, the deposition temperature for the single crystalline semiconductor-carbon alloy layer can be from 800° C. to 2,000° C., and typically from 900° C. to 1,300° C., although lesser and greater deposition temperatures can also be employed. Further, depending on the composition and the desired deposition rate, the deposition temperature can be adjusted.
During the deposition step, the pressure in the process chamber can be maintained in a range from 0.1 mTorr to 100 mTorr, and typically from 1 mTorr to 10 mTorr, although lesser and greater deposition pressure can also be employed. The semiconductor-containing precursor includes the semiconductor component of a single crystalline semiconductor-carbon alloy layer, and the carbon-containing precursor includes carbon. Specifically, each molecule of the semiconductor-containing precursor includes a semiconductor atom or component atoms of a compound semiconductor material. Further, each molecule of the semiconductor-containing precursor includes at least one hydrogen atom, at least one chlorine atom, at least one fluorine atom, or a combination thereof. Each molecule of the carbon-containing precursor includes at least one unsaturated hydrocarbon atom.
The single crystalline semiconductor-carbon alloy layer can have an atomic carbon concentration consistent with a (0001) surface orientation during growth and a hexagonal crystal structure if deposited directly on a (0001) plane of a sapphire substrate. In this case, a (0001) surface of the single crystalline semiconductor-carbon alloy layer contacts a (0001) plane of the sapphire substrate at an interface. The single crystalline semiconductor-carbon alloy layer can have an atomic carbon concentration consistent with a (110) surface orientation during growth and a cubic crystal structure if deposited directly on a (1102) plane of a sapphire substrate. In this case, a (111) surface of the single crystalline semiconductor-carbon alloy layer contacts a (1102) plane of the sapphire substrate at an interface.
In case the single crystalline semiconductor-carbon alloy layer is a single crystalline silicon-carbon alloy layer, the semiconductor-containing precursor includes silicon. For example, the single crystalline semiconductor-carbon alloy layer can have an atomic carbon concentration consistent from 40% to 60%. The carbon-containing precursor can include carbon and hydrogen. In case the single crystalline semiconductor-carbon alloy layer is a single crystalline silicon-carbon alloy layer, the semiconductor-containing precursor can be selected from SiH4, Si2H6, SiH3Cl, SiH2Cl2, SiHCl3, and SiCl4. If the single crystalline semiconductor-carbon alloy layer includes germanium or a compound semiconductor in addition to silicon or in lieu of silicon, the semiconductor-containing precursor can be selected accordingly. The carbon-containing precursor can be selected from C2H2, C2H4, CnH2n−2, and CnH2n, wherein n is an integer greater than 2. If the single crystalline semiconductor-carbon alloy layer is a single crystalline silicon carbide layer, the silicon-containing reactant gas can be 100% silane (SiH4) and the carbon-containing reactant gas can be 50% ethelene (C2H4) with helium as the balance gas. The flow rate of 100% silane can be from 2 sccm to 30 sccm, and the flow rate of 50% ethelene can be from 2 sccm to 40 sccm.
If the single crystalline silicon-carbon alloy layer is a single crystalline silicon carbide layer and a single crystalline sapphire substrate having a (0001) surface orientation is employed, a single crystalline silicon carbide layer with a hexagonal crystal structure, i.e., in alpha phase, and a (0001) surface orientation can be epitaxially deposited. Thus, the first exemplary structure can be formed such that the single crystalline semiconductor-carbon alloy layer 120 is the single crystalline silicon carbide layer in alpha phase. If the single crystalline silicon-carbon alloy layer is a single crystalline silicon carbide layer a single crystalline sapphire substrate having a (1102) surface orientation is employed, a single crystalline silicon carbide layer with cubic crystal structure of the zinc blende type, i.e., in beta phase, and a (110) surface orientation can be epitaxially deposited. Thus, the second exemplary structure of
The composition of the single crystalline semiconductor-carbon alloy layer, and correspondingly, the composition of the semiconductor-containing precursor and the carbon-containing precursor are selected to maintain a (0001) growth plane and a hexagonal crystal structure if the single crystalline semiconductor-carbon alloy layer is formed on a (0001) sapphire substrate Likewise, if the single crystalline semiconductor-carbon alloy layer is formed on a (1102) sapphire substrate, the composition of the semiconductor-containing precursor and the carbon-containing precursor are selected to maintain a (110) growth plane and a cubic crystal structure.
Once the deposition step is completed, the process chamber can be evacuated to a base pressure, and the temperature of the process chamber can be lowered to a temperature suitable for unloading of the first and/or second exemplary structure.
It is noted that, by reducing the deposition temperature or by otherwise providing inferior growth conditions, for example, by providing an ambient including a significant level of residual gases within a deposition chamber, the single crystalline semiconductor-carbon alloy layer 220 can be replaced with a polycrystalline semiconductor-carbon alloy layer having the same crystallographic alignment with underlying crystalline structures, while including grain boundaries between the various grains.
Samples of the first exemplary structure and the second exemplary structure have been formed and tested in the course of experiments leading to the instant invention employing the methods describe above. These samples have been subjected to various types of analysis including x-ray diffraction, secondary ion mass spectroscopy, and transmission electron microscopy.
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While the invention has been described in terms of specific embodiments, it is evident in view of the foregoing description that numerous alternatives, modifications and variations will be apparent to those skilled in the art. Accordingly, the invention is intended to encompass all such alternatives, modifications and variations which fall within the scope and spirit of the invention and the following claims.
The present application is related to co-assigned and co-pending U.S. application Ser. Nos. 12/844,029 filed on Jul. 27, 2010 and (Attorney Docket No: YOR920100055US1; SSMP 24972 being filed on the same date herewith).
This invention was made with government support under Defense Advanced Research Project Agency (DARPA) CERA Contract No. FA8650-08-C-7838 awarded by the U.S. Department of Defense. The government has certain rights in this invention.