Susceptor for MOCVD reactor | Patent Publication Number 20060269390
US 20060269390 A1Steven DenBaars
Max Batres
Michael Coulter
A susceptor for holding semiconductor wafers in an MOCVD reactor during growth of epitaxial layers on the wafers is disclosed. The susceptor comprises a base structure made of a material having low thermal conductivity at high temperature, and has one or more plate holes to house heat transfer plugs. The plugs are made of a material with high thermal conductivity at high temperatures to transfer heat to the semiconductor wafers. A metalorganic organic chemical vapor deposition reactor is also disclosed utilizing a susceptor according to the present invention.
- 19. (not entered)
- 20. A susceptor for holding semiconductor wafers in a reactor for growing epitaxial layers, comprising: na high thermal conductivity at high temperatures material under said wafers to transfer heat to the semiconductor wafers; and a low thermal conductivity at high temperature material in all other areas.
- 1-18. (canceled)
1. Field of the Invention
This invention relates to metalorganic chemical vapor deposition (MOCVD) reactors and more particularly to susceptors used in MOCVD reactors.
2. Description of the Related Art
Growth of gallium nitride (GaN) based semiconductor devices in MOCVD reactors is generally described in DenBaars and Keller, Semiconductors and Semimetals, Vol. 50, Academic Press Inc., 1997, p. 11-35. MOCVD is a nonequilibrium growth technique that relies on vapor transport of the precursers and subsequent reactions of group III alkyls and group V hydrides in a heated zone. Growth gasses and dopants are supplied to the reactor and are deposited as epitaxial layers on a substrate or wafer. One or more wafers usually rest on a structure of graphite called a susceptor that can be heated by a radio frequency (RF) coil, resistance heated, or radiantly heated by a strip lamp or coil heater. During the growth process, the heated susceptor heats the wafers.
Conventional susceptors 10 are usually formed from a monolithic structure of graphite or coated graphite that absorbs heat from the heater element and conducts it to the wafers in contact with the susceptor 10. The entire susceptor 10 is heated uniformly to achieve consistent growth conditions across the surfaces of the wafers. During fabrication of the epitaxial layers, materials will not only deposit on the heated wafer, but will also deposit on the heated susceptor 10. This can cause deposition of significant amounts of GaN, InGaN, AlInGaN, and similar compounds on the susceptor surfaces. The result is a buildup of reaction deposits on the susceptor that can adversely impact subsequent fabrication steps. For instance, the deposits can act as impurities during subsequent growth of the epitaxial layers and can also result in poor interfaces transition between different layers. For example, if a layer using an indium source gas was grown, indium can be deposited on the susceptor and though the next layer to be grown does not include indium, indium from the susceptor surfaces can be included in the transition between layers. These impurities can cause poor device performance and can prevent consistent reproduction of semiconductor devices on the wafer.
Another disadvantage of conventional susceptors is that the heating element heats the entire susceptor, not just the areas under or around the wafers. This requires large amounts of heat because the susceptor has a relatively large surface area in comparison to the wafers. Most of the energy is wasted by not heating the wafers. This taxes the heater, contributing to early heater failures. Also, more reactants are consumed due to the fact that the entire susceptor is at a temperature sufficient for chemical vapor deposition.
Another disadvantage of conventional susceptors is that they are difficult to manufacture. They must be machined from a large section of graphite and if any part of the susceptor is damaged the entire structure can be unusable. The fabrication of the depressions can be extremely difficult because they are off set from the structure's longitudinal axis. The depressions cannot be machined using a simple lathe, but must involve more complex processes. For the same reasons it is very difficult to modify the shape of the surface of the depressions to compensate for temperature non-uniformity.
The present invention discloses a susceptor for holding semiconductor wafers in a reactor during growth of epitaxial layers on the wafers. The susceptor comprises a base structure having a base plate and a sleeve that are both made of a material having low thermal conductivity at high temperature. The base plate has one or more plate holes. One or more heat transfer plugs are also included, with each plug housed within a respective one of the one or more plate holes. The heat transfer plugs are made of a material with high thermal conductivity at high temperatures to transfer heat to the semiconductor wafers.
The present invention also discloses a reactor for growing epitaxial layers on semiconductor wafers, including a reactor chamber housing a heating element and susceptor. The susceptor holds the semiconductor wafers and is arranged over the heater element. The susceptor comprises a base structure having a base plate and a sleeve and that are made of a material having low thermal conductivity at high temperature, with the base plate having one or more plate holes with a heat transfer plug held within a respective one of the plate holes. The wafers are arranged on the plugs, and the plugs are made of a material with high thermal conductivity at high temperatures. The plugs transfer heat from the heater element to the semiconductor wafers. A growth gas inlet is also included to provide gasses to grow epitaxial layers on the semiconductor wafers.
Reduced amounts of reactants are deposited on the susceptor embodiments disclosed herein, thereby reducing unwanted impurities during subsequent fabrication steps. The epitaxial layers can also be grown using less energy and consuming less source material because most of the heat from the reactor's heating element passes through the heat transfer plugs instead of heating the entire susceptor. The susceptor can also be manufactured using less complex processes because it does not need to be machined from a solid piece of graphite. Also, the heat transfer plugs can be more easily machined so that their surface adjacent to the wafer has a convex or concave shape to compensate for any temperature not-uniformity.
These and other features and advantages of the invention will be apparent to those skilled in the art from the following detailed description, taken together with the accompanying drawings, in which:
The susceptor 20 includes a base structure 22 made of a base plate 24 and a cylindrical sleeve 26, which can be separate or manufactured as one structure. The base plate 24 has circular through holes 28 equally spaced around the susceptor's longitudinal axis 30. The number of through holes 28 can vary depending on the number of wafers that the susceptor 20 is designed to hold during growth.
The base structure 22 should be made of a rigid material that has a low thermal conductivity at high temperature so that it transmits less heat from the MOCVD reactor's heating element. It should also be made of a material that is reflective so that it reflects the heating element's radiative heat to further reduce the amount of heat it transmits. It should also have a low thermal expansion, so that its expansion matches that of the other susceptor components.
The base structure 22 can be made of many different materials such as boron nitride, fused quartz, aluminum nitride, or a ceramic, with the aluminum nitride and ceramic embodiments being coated with a material to reduce their reactance with the source gasses. A preferred base structure 22 is made of boron nitride or fused quartz covered by boron nitride. These materials have high thermal conductivity at low temperature, low thermal conductivity at high temperature, and boron nitride is white, which enhances the structure's reflectivity. The base structure 22 is manufactured using known methods.
The base structure 22 can have many different dimensions. A suitable height for the cylindrical sleeve is approximately 2 inches and a suitable diameter is approximately 6.2 inches for a susceptor holding three 2 inch wafers. The base plate 24 also has a suitable diameter of approximately 6.2 inches, with the plate holes 28 equally spaced around the center of the base plate 24. A suitable diameter for the plate holes 28 is approximately 2.3 inches. The base plate 24 and the sleeve 26 can have many different thicknesses, with a suitable thickness being approximately 0.2 inches.
The susceptor 20 also includes heat transfer plugs 32, each of which fit within a respective plate hole 28. Semiconductor wafers are placed in contact with the plugs 32 during growth of the epitaxial layers and heat from the heating element should be efficiently conducted through the plugs 32, to the wafers. The plugs 32 are preferably made of a material having high thermal conductivity at high temperature and a dark color, both of which promote heat conduction. The preferred material for the plugs 32 is graphite or silicon carbide coated graphite. Each of the plugs 32 has an axial lip 33 around its outer surface, which rests on one of the axial ledges 34 on the inside surfaces of the through holes 28, such that a respective plug 32 rests within one of the holes 28.
A faceplate 36 can also be included that has holes 38 that align with the base structure's plate holes 28. The faceplate is arranged on the base structure's base plate 24 with the faceplate and base structure holes 38, 28 aligned. Only the plugs 32 are uncovered by the faceplate holes 38 and when a wafer is placed over the plug 32, only the wafer is uncovered by the holes 38.
The susceptor 20 works without the faceplate 36, but small amounts of reactants can deposit on the base structure 22 during epitaxial growth. The faceplate 36 provides a surface with a greater resistance to deposition of reaction species, with the surface also being easy to clean. It is preferably infrared transparent so that is does not absorb optical heat. It should also be made of a material that does not react with MOCVD source gasses. It can be made of materials such as quartz, pure silicon carbide, sapphire, silicon, coated graphite, graphite or tungsten, with a preferred material being quartz. Deposits can be cleaned from quartz by etching.
The faceplate 36 should have approximately the same diameter as the base plate 22 and its holes 38 should have the same or slightly smaller diameter as the plate holes 28. The faceplate 36 can have many different thicknesses with a suitable thickness being approximately 0.16 inches.
The susceptor 20 is designed to spin over the reactor's heating element during growth, so the face plate 36 should be mounted to the base structure 22. Different mounting methods can be used including, but not limited to, pins on the structure 22 mated with mounting holes, axial slots or J-slots in the faceplate 36. Alternatively, rotatable hooks can be included on the structure to mate with slots in the faceplate 36. In one embodiment, the hooks can be turned away from the center of the base plate 24 and the faceplate 36 is then placed over the base plate 24, with the stem of the hooks aligned with a respective slot. The hooks are then rotated so they are directed toward the center of the base plate 24. In the embodiment shown in
A space can be included between the faceplate 36 and the base structure 22 to limit the conducted heat due to contact between the faceplate 36 and the base plate 24. This is best accomplished by including a raised section on the surface of the base plate 24, around its edge.
The susceptor 20 can be used in MOCVD reactors where the susceptor is arranged at the bottom of the reactor with the circular plate facing up. Growth gasses enter the reactor from the top or sides and are deposited on the uncovered wafers that are held over the plugs 40.
This susceptor 20 promotes the transfer of heat from the reactor's heating element through the plugs 32, which reduces the amount of deposits on the surface of the base structure 22. Reduction of such deposits reduces the presence of unwanted compounds during fabrication of subsequent layers. The fabrication process requires less growth gas because most of the gasses are deposited on the wafer. The resulting semiconductor device has sharper interfaces and lower levels of unwanted impurities. This increases the yield and reproducibility of the epitaxial growth process.
This design also reduces the amount of power required to maintain the wafers at any given temperature compared to conventional susceptors. The heat primarily passes through the plugs only, instead of the entire susceptor as in the prior art. This allows for the use of smaller and less expensive components in the heater control assembly, increases the life of the heater assembly, and allows the growth of the epitaxial layers using less energy and source gasses.
The plug can have many different thicknesses, with a suitable thickness being approximately 0.33 inches. The ridge 54 can be many different sizes, with a suitable size being 0.002 inches high and 0.003 inches wide.
Prior to growth of the epitaxial layers, the wafers 52 and transfer plugs 50 are placed in the through holes 28 and the faceplate 36 is mounted to base structure 22 with the faceplate holes 38 aligned with the base structure's holes 28. The wafers 52 are uncovered by the faceplate 36 and when the plugs 50 are heated by the MOCVD's heating element, the wafers 52 are also heated. Growth gasses are fed into the reactor as the susceptor assembly 20 spins and epitaxial layers are grown on the wafers 52.
A carrier gas 76 is supplied to a gas line 78, the carrier gas being an inert gas such as hydrogen or nitrogen. The carrier gas 76 is also supplied through mass flow controllers 80a, 80b, 80c to respective bubblers 82a, 82b, 82c. Bubbler 82a can have a growth compound, such as an alkylated compound having a methyl group, e.g. trimethyl gallium (TMG), trimethyl aluminum (TMA) or timethyl indium (TMI). Bubbler 82b and 82c may also contain a similar methyl group compound to be able to grow an alloy of a Group III compound. The bubblers 82a, 82b, 82c are typically maintained at a predetermined temperature by constant temperature baths 84a, 84b, 84c to ensure a constant vapor pressure of the metal organic compound before it is carried to the reaction chamber 72 by the carrier gas 76.
The carrier gas 76, which passes through bubblers 82a, 82b, 82c, is mixed with the carrier gas 76 flowing within the gas line 78 by opening the desired combination of valves 86a, 86b, 86c. The mixed gas is then introduced into the reaction chamber 72 through a gas inlet port 88 formed at the upper end of the reaction chamber 72. A shower head inlet (not shown) can be included at the inlet port 88.
A nitrogen containing gas 90 such as ammonia, is supplied to the gas line 78 through a mass flow controller 92 and the flow of nitrogen containing gas is controlled by valve 94. If the carrier gas 76 is mixed with the nitrogen containing gas 90 and the TMG vapor within the gas line 78 and then introduced into the reaction chamber 72, the elements are present to grow gallium nitride on the wafer through thermal decomposition of the molecules present in the TMG and ammonia containing gas.
To dope alloys of gallium nitride on the wafer, one of the bubblers 82a, 82b, 82c not being used for the TMG is used for a dopant material, which is usually Magnesium (Mg) or Silicon (Si), but can be other material such as beryllium, calcium, zinc, or carbon. Bubbler 82b or 82c can be used for an alloy material such as boron aluminum, indium, phosphorous, arsenic or other materials. Once the dopant and alloy are selected and one of the valves 86a, 86b, 86c is opened to allow the dopant to flow into gas line 78 with the gallium and nitrogen containing gas 90, the growth of the doped layer of gallium nitride takes place on wafer.
The gas within the reaction chamber 72 can be purged through a gas purge line 96 connected to a pump 98 operable under hydraulic pressure. Further, a purge valve 100 allows gas pressure to build up or be bleed off from the reaction chamber 72.
The growth process is typically stopped by shutting off the gallium and dopant sources by closing valves 86a and 86b, and keeping the nitrogen containing gas and the carrier gas flowing. Alternatively, the reaction chamber 72 can be purged with a gas 102 that can be controlled through a mass flow controller 104 and valve 106. The purge is aided by opening valve 100 to allow the pump 98 to evacuate the reaction chamber 72 of excess growth gasses. Typically, the purge gas 102 is hydrogen, but can be other gasses. The wafer is then cooled by turning off power to the heater element.
Although the present invention has been described in considerable detail with reference to certain preferred configurations thereof, other versions are possible. The susceptors according to the present invention would work without a faceplate 36. As described above, susceptors according to the present invention can be used in many different reactors beyond MOCVD reactors and can be used in many different types of MOCVD reactors. The susceptors can be made of many different materials with many different dimensions. They can also be arranged differently with one different arrangement having the plugs 32 housed within the faceplate holes 38. Therefore, the spirit and scope of the appended claims should not be limited to the preferred versions in the specification.