A device for growing large-sized monocrystalline crystals, including a crucible adapted to grow crystals from a material source and with a seed crystal and including therein a seed crystal region, a growth chamber, and a material source region; a thermally insulating material disposed outside the crucible and below a heat dissipation component; and a plurality of heating components disposed outside the thermally insulating material to provide heat sources, wherein the heat dissipation component is of a heat dissipation inner diameter and a heat dissipation height which exceeds a thickness of the thermally insulating material.
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1. A device for growing monocrystalline crystals, comprising:
a crucible adapted to grow crystals from a material source and with a seed crystal and including therein a seed crystal region, a growth chamber, and a material source region;
a thermally insulating material disposed outside the crucible;
a heat dissipation component disposed on top of the crucible; and
a plurality of heating components disposed outside the thermally insulating material to provide heat sources;
wherein the heat dissipation component is a hollow-cored cylinder surrounded by the thermally insulating material and directly contacted with the crucible at the bottom thereof so as to expose at least a part of top surface of the crucible, and the heat dissipation component is of a heat dissipation inner diameter and a heat dissipation height which exceeds a thickness of the thermally insulating material.
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This non-provisional application claims priority under 35 U.S.C. § 119(a) on Patent Application No(s). 105127344 filed in Taiwan, R.O.C. on Aug. 26, 2016, the entire contents of which are hereby incorporated by reference.
The present invention relates to devices for crystal growth and, more particularly, to a device for growing monocrystalline crystals from silicon carbide and nitrides.
Due to rapid development of modern technology and enhancement of quality of life, various 3C high-tech electronic products are becoming thinner, lighter, smaller and more versatile. Therefore, various electronic devices are made from semiconductors, such as silicon carbide (SiC) and group III nitrides (e.g., GaN and AlN). In this regard, silicon carbide and group III nitrides display high physical strength, high resistance to corrosion, and excellent electronic properties, such as high hardness of radiation, high breakdown field strength, wide bandgap, high saturated electron drift velocity, and satisfactory high-temperature operability.
Conventional techniques, such as physical vapor transport (PVT) and physical vapor deposition (PVD), are for use in growing crystals from silicon carbide and group III nitrides include as well as mass production of crystals. PVT involves allowing a silicon carbide powder and a group III nitride powder to undergo sublimation in a muffle furnace and driving gaseous silicon carbide and gaseous group III nitrides to a seed crystal by a temperature gradient so as to undergo a crystal growth process. In general, growing silicon carbide crystals by PVT entails: providing a seed crystal; putting the seed crystal in a crucible which comprises a growth chamber, a seed crystal region (inclusive of a holder disposed above the growth chamber, adapted to fix the seed crystal in place, and positioned at the relative cold end of a heat field device for providing the temperature gradient), and a material source region disposed below the growth chamber and adapted to contain a material source; filling the material source region with a carbide raw material so that the carbide raw material undergoes sublimation to become gas molecules; and conveying the gas molecules to a seed crystal wafer to undergo deposition and crystal growth. Applying PVT to growing crystals from silicon carbide and group III nitrides has disadvantages described below. Take silicon carbide as an example, defects of a graphite thermally-conductive layer extend into a wafer. In 1993, Stein discovered a hexagonal vacancy in a silicon carbide wafer produced by PVT and suggested that it results from planar evaporation of the back of the wafer. The nucleation site of the hexagonal vacancy is located at an imperfect point of the graphite thermally-conductive layer between a seed crystal and a seed pad. During the process of crystal growth, the growth of the bottom (near the seed crystal) of the hexagonal vacancy and the evaporation which occurs at the top (near the growth surface) of the hexagonal vacancy together lead to the movement of the hexagonal vacancy. The hexagonal vacancy originates from the imperfect point of the graphite thermally-conductive layer between the seed crystal and the seed pad. The aforesaid phenomenon also causes 6H (or 15R) polycrystalline insertions, carbon-rich depositions, and pyrolysis-related holes. In view of this, the prior art discloses precluding the defects by plating a uniform photoresist layer on the back of the seed crystal to stop silicon carbide from undergoing local sublimation on the back of the seed crystal which might otherwise occur because of the poor heat transfer caused by the holes, but at the expense of the rate of the growth of the wafer and reproducibility.
Since the quality of a wafer produced by PVT depends on the temperature at which the crystal growth process is carried out, the prior art discloses improving a required apparatus to control the growth process temperature. U.S. Pat. No. 5,968,261 discloses forming a cavity in a graphite crucible and applying a thermally insulating material to the inner wall of the cavity to increase the efficiency of the heat dissipation that takes place on the back of a seed crystal. US20060213430 discloses changing the distance between a seed crystal and a holder thereof to control the efficiency of heat transfer between the seed crystal and the holder as well as heat radiation. U.S. Pat. No. 7,351,286 discloses positioning a seed crystal in a manner to reduce the bending of the seed crystal and the effect of a stress thereon. U.S. Pat. No. 7,323,051 discloses positioning a seed crystal by a porous matter disposed on the back of the seed crystal and providing a vapor blocking layer for reducing the sublimation which occurs to the seed crystal. U.S. Pat. No. 7,524,376 provides a thin-walled crucible and discloses growing an aluminum nitride wafer by PVT to reduce a thermal stress. U.S. Pat. No. 8,147,991 discloses controlling the efficiency of heat transfer by adjusting the distance between a seed crystal and a holder thereof.
The aforesaid prior art involves modifying the shape of a crucible or the shape of a seed crystal holder. However, after a growing wafer has attained a large size, the aforesaid prior art fails to dissipate heat sufficiently from the large-sized wafer, further control the shape of the interface of the growth of the wafer, and speed up the growth rate. In view of this, it is important to provide a device adapted for growing monocrystalline crystals and equipped with a heat dissipation component conducive to high efficiency of heat dissipation of large-sized wafers, good balance between process costs and efficiency, and the growth of large-sized monocrystalline crystals by PVT.
In view of the aforesaid drawbacks of the prior art, it is an objective of the present invention to provide a device for growing monocrystalline crystals. The device comprises a crucible, a thermally insulating material, and a plurality of heating components, and features a heat dissipation inner diameter, a heat dissipation outer diameter, and a heat dissipation height, so as to effectively control a heat field. Furthermore, the device features an axial temperature gradient whereby high-quality monocrystalline crystals are grown.
To achieve the above and other objectives, the present invention provides a device for growing monocrystalline crystals, comprising: a crucible adapted to grow crystals from a material source and with a seed crystal and including therein a seed crystal region, a growth chamber, and a material source region; a thermally insulating material disposed outside the crucible and below a heat dissipation component; and a plurality of heating components disposed outside the thermally insulating material to provide heat sources, wherein the heat dissipation component is of a heat dissipation inner diameter and a heat dissipation height which exceeds the thickness of the thermally insulating material.
The crucible is a graphite crucible (but the present invention is not limited thereto.) The seed crystal region disposed at an upper part within the crucible includes a holder for fixing the seed crystal in place. The seed crystal is made of silicon carbide or a nitride (but the present invention is not limited thereto.) The seed crystal is a monocrystalline wafer of a thickness of at least 350 μm and a diameter of 2-6 inches and is for growing monocrystalline crystals which outgrow the seed crystal in size. The monocrystalline wafer is made of silicon carbide or a nitride (but the present invention is not limited thereto.) The material source region disposed at the lower part within the crucible contains a material source. The material source is a silicon carbide powder or a nitride powder (but the present invention is not limited thereto.)
The crucible is enclosed by a thermally insulating material. The thermally insulating material is disposed below a heat dissipation component. The heat dissipation component enhances the heat dissipation taking place in the seed crystal region, controls a heat field in the crucible, increases the axial temperature gradient to thereby increase the wafer growth rate, increases the radial temperature gradient to thereby control the interface shape, thereby enabling the production of high-quality silicon carbide monocrystalline crystals. The thermally insulating material is a graphite felt (but the present invention is not limited thereto.) The graphite felt and the heat dissipation component are either integrally formed or separately formed. The thermally insulating material and heat dissipation component are made of the same material or different materials. The heat dissipation component is made of a porous, thermally insulating carbon material, a graphite, or a graphite felt (but the present invention is not limited thereto.) The heat dissipation component is a hollow-cored cylinder (for example, chimney-shaped), a hollow-cored cuboid, or any other geometric cuboid. Hence, the heat dissipation component has a heat dissipation inner diameter, a heat dissipation outer diameter, and a heat dissipation height. The heat dissipation inner diameter equals 10˜250 mm or 1%˜85% of the outer diameter of an upper portion of the crucible. The heat dissipation outer diameter equals 15˜300 mm or 3%˜100% of the outer diameter of an upper portion of the crucible. The heat dissipation height equals 5˜200 mm (and thus exceeds the thickness of the thermally insulating material.)
The plurality of heating components is disposed outside the thermally insulating material to provide heat sources for heating up the device. Each heating component is a heating coil or a heating resistance wire/netting.
The above summary, the detailed description below, and the accompanying drawings further explain the technical means and measures taken to achieve predetermined objectives of the present invention and the effects thereof. The other objectives and advantages of the present invention are explained below and illustrated with the accompanying drawings.
The preferred embodiment of the present invention is illustrated with a specific embodiment. Hence, persons skilled in the art can easily gain insight into the advantages and effects of the present invention.
The present invention provides a device for growing monocrystalline crystals. When applied to physical vapor transport (PVT), the device for growing monocrystalline crystals is effective in controlling a heat field, increasing an axial temperature difference, suppressing the growth of a polycrystalline region during the initial stage of the growth of monocrystalline crystals, increasing the range of a monocrystalline region in the course of the growth of a convex interface thereof, bringing about expansive growth of the monocrystalline region, reducing the growth of a polycrystalline crystal and its effect on a monocrystalline crystal, speeding up crystal growth, increasing the yield of crystal growth, and enabling mass production of crystals.
Referring to
Referring to
Referring to
Referring to
axial
radial
maximum flux of
temperature
temperature
radiation heat above
gradient (° C./cm)
gradient (° C./cm)
crucible (105 W/m2)
comparative
35.34
1.93
3.17
embodiment
preferred
71.84
−1.54
5.90
embodiment
According to the present invention, with the heat dissipation component being provided to control heat dissipation in the seed crystal region, the growth of the polycrystalline region is effectively suppressed while crystal growth is underway to produce large-sized monocrystalline crystals. Furthermore, growth efficiency increases toward the center of the seed crystal to thereby produce a 6-inch monocrystalline crystal ball with a convex wafer interface. In addition, compared with the prior art, the present invention features an enhanced crystal growth rate and thus enables mass production of large-sized monocrystalline crystals.
The above embodiments are illustrative of the features and effects of the present invention rather than restrictive of the scope of the substantial technical disclosure of the present invention. Persons skilled in the art may modify and alter the above embodiments without departing from the spirit and scope of the present invention. Therefore, the scope of the protection of rights of the present invention should be defined by the appended claims.
Kuo, Chih-Wei, Ma, Dai-Liang, Lin, Bo-Cheng, Ko, Cheng-Jung, Chen, Hsueh-I, Zhao, Ying-Cong, Yeh, Shu-Yu
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