CRYSTAL PULLING SYSTEM AND METHODS FOR PRODUCING MONOCRYSTALLINE INGOTS WITH REDUCED EDGE BAND DEFECTS
A crystal pulling system for growing a monocrystalline ingot from a melt of semiconductor or solar-grade material includes a crucible for containing the melt of material, a pulling mechanism configured to pull the ingot from the melt along a pull axis, and a multi-stage heat exchanger defining a central passage for receiving the ingot as the ingot is pulled by the pulling mechanism. The heat exchanger defines a plurality of cooling zones arranged vertically along the pull axis of the crystal pulling system. The plurality of cooling zones includes two enhanced-rate cooling zones and a reduced-rate cooling zone disposed vertically between the two enhanced-rate cooling zones.
This application is a divisional application of U.S. patent application Ser. No. 16/237,071, filed on Dec. 31, 2018, which is a divisional application of U.S. patent application Ser. No. 15/297,853, filed on Oct. 19, 2016, which claims priority to U.S. Provisional Patent Application Ser. No. 62/243,322, filed on Oct. 19, 2015, the disclosures of which are hereby incorporated by reference in their entirety.
FIELDThe field relates generally to preparation of single crystals of semiconductor or solar-grade material and, more specifically, to crystal pulling systems including heat exchangers and related methods for producing monocrystalline ingots with reduced edge band defects.
BACKGROUNDSingle crystal material, which is the starting material for fabricating many electronic components such as semiconductor devices and solar cells, is commonly prepared using the Czochralski (“CZ”) method. Briefly, the Czochralski method involves melting polycrystalline source material, such as polycrystalline silicon (“polysilicon”), in a crucible to form a silicon melt, and then pulling a single-crystal ingot from the melt.
The continuously shrinking size of modern electronic devices imposes challenging restrictions on the quality of the silicon substrate, which is determined, at least in part, by the size and the distribution of the grown-in microdefects. Most of the microdefects formed in silicon crystals grown by the Czochralski process are agglomerates of intrinsic point defects of silicon (i.e., vacancies and self-interstitials) or oxide precipitates.
Attempts to produce substantially defect-free single crystal silicon often include controlling the ratio of the crystal pull-rate (v) to the magnitude of the axial temperature gradient in the vicinity of the melt/crystal interface (G). For example, some known methods include controlling the v/G ratio near a critical v/G value at which vacancy and interstitial defects are incorporated into the growing crystal ingot in very low and comparable concentrations, mutually annihilating each other and thus suppressing the potential formation of any microdefects at lower temperatures. However, as described in U.S. Pat. No. 8,673,248 to Kulkarni, controlling the v/G ratio near such a critical v/G value may form an annular ring or “band” of relatively large and/or concentrated agglomerated defects (such as voids and oxygen precipitates) extending a distance radially inward from the lateral surface or circumferential edge of the silicon crystal ingot, referred to herein as a “defect edge band” or simply, “defect band”.
Such a defect band is generally of lower quality than other portions of the silicon crystal ingot located radially inward from the defect band, and can significantly reduce the yield of the crystal ingot. For example, increasingly stringent requirements on the quality of wafers for memory devices have increased the required breakdown voltage for gate oxide integrity (GOI) tests, used to evaluate the quality of silicon or semiconductor wafers for application in memory devices (e.g., SRAM, DRAM). As a result, more GOI failures occur near or within the defect edge band of substantially defect-free silicon wafers, reducing the yield.
Known methods and crystal pulling systems for addressing and/or reducing the defect edge band in silicon or semiconductor crystal ingots have been less than optimal for certain applications. Accordingly, a need exists for crystal pulling systems and methods for producing monocrystalline ingots with fewer edge band defects and edge band defects having a smaller average size.
This Background section is intended to introduce the reader to various aspects of art that may be related to various aspects of the present disclosure, which are described and/or claimed below. This discussion is believed to be helpful in providing the reader with background information to facilitate a better understanding of the various aspects of the present disclosure. Accordingly, it should be understood that these statements are to be read in this light, and not as admissions of prior art.
BRIEF SUMMARYIn one aspect, a crystal pulling system for growing a monocrystalline ingot from a melt of semiconductor or solar-grade material includes a crucible for containing the melt of semiconductor or solar-grade material, a pulling mechanism configured to pull the ingot from the melt along a pull axis, and a multi-stage cooling system configured to cool the ingot at different cooling rates as the ingot is pulled from the melt by the pulling mechanism. The cooling system includes an annular heat shield and a multi-stage heat exchanger. The heat shield is positioned concentric with the crucible and defines an elongate passage for receiving the ingot. The multi-stage heat exchanger is positioned within the passage defined by the heat shield, and including a fluid-cooled housing that defines a central passage for receiving the ingot. The housing has an upper portion and a lower portion spaced vertically from the upper portion by an annular gap.
In another aspect, a crystal pulling system for growing a monocrystalline ingot from a melt of semiconductor or solar-grade material includes a crucible for containing the melt of semiconductor or solar-grade material, a pulling mechanism configured to pull the ingot from the melt along a pull axis, and a multi-stage heat exchanger defining a central passage for receiving the ingot as the ingot is pulled by the pulling mechanism. The heat exchanger defines a plurality of cooling zones arranged vertically along the pull axis of the crystal pulling system. The plurality of cooling zones includes two enhanced-rate cooling zones and a reduced-rate cooling zone disposed vertically between the two enhanced-rate cooling zones.
In yet another aspect, a method of growing a monocrystalline ingot from a melt of semiconductor or solar-grade material includes preparing the melt of semiconductor or solar-grade material in a crucible, lowering a seed crystal into contact with the melt to initiate growth of the monocrystalline ingot, growing the monocrystalline ingot by pulling the seed crystal away from the melt, and controlling the cooling rate of the ingot by pulling the ingot through a multi-stage heat exchanger. Controlling the cooling rate of the ingot includes cooling an axial segment of the ingot at a first, initial cooling rate as the ingot is pulled from melt, cooling the axial segment of the ingot at a second cooling rate less than the first cooling rate as the ingot is pulled from the melt, and cooling the axial segment at a third cooling rate greater than the second cooling rate as the ingot is pulled from the melt.
Various refinements exist of the features noted in relation to the above-mentioned aspects. Further features may also be incorporated in the above-mentioned aspects as well. These refinements and additional features may exist individually or in any combination. For instance, various features discussed below in relation to any of the illustrated embodiments may be incorporated into any of the above-described aspects, alone or in any combination.
Corresponding reference characters indicate corresponding parts throughout the several views of the drawings.
DETAILED DESCRIPTIONThe systems and methods of this disclosure facilitate reducing the size and concentration of defects that form the grown-in defect edge band in monocrystalline ingots grown by the Czochralski method, such as single crystal silicon ingots. In particular, the systems and methods described facilitate reducing the concentration and/or the size of defects incorporated into the crystal ingot during growth by reducing and/or controlling the lateral incorporation and transport of defects, such as vacancies and oxygen impurities, as the crystal ingot is grown from a melt. The systems and methods described also facilitate reducing the size of defects in crystal ingots by reducing and/or controlling the nucleation of agglomerated defects, such as voids and oxygen precipitates, as the crystal ingot is grown.
Additionally, the systems and methods of this disclosure facilitate reducing and/or controlling lateral incorporation and nucleation of defects by controlling the cooling rate of the ingot and by controlling the profile of the melt/crystal interface during growth of the crystal. In particular, the systems and methods described use a multi-stage cooling system (broadly, a temperature control system) that subjects the ingot to multiple different cooling rates as the ingot is pulled from the melt. Use of the multi-stage cooling system facilitates closely controlling the various transport and nucleation mechanisms of defects at various stages of crystal growth, and thereby facilitates reducing the size and/or concentration of defects incorporated into the crystal during growth. Moreover, the present disclosure provides a method for determining a desired or target melt/crystal interface profile for reducing and/or controlling lateral incorporation of defects, and for controlling process parameters during crystal growth to achieve the desired melt/crystal interface profile. Notably, the systems and methods described herein facilitate reducing the size of voids and oxygen precipitates in the grown-in edge band of substantially defect-free or “perfect-silicon” crystals without any post growth thermal treatment in crystal or wafer form.
Referring to
The illustrated crystal pulling system 100 generally includes a housing 102 defining a growth chamber 104 and an ingot removal chamber 106 connected to and positioned above the growth chamber 104. A graphite support or susceptor 108 is supported by a rotatable shaft 110 within the growth chamber 104. A crucible 112 containing a melt 114 of semiconductor or solar-grade material (e.g., silicon) from which a monocrystalline ingot 116 is pulled by a pulling mechanism 118 is supported within the growth chamber 104 by the susceptor 108. One or more heating elements 120 are positioned proximate the crucible 112 for supplying thermal energy to the system 100. During the crystal growth process, a seed crystal 122 is lowered by the pulling mechanism 118 into contact with the melt 114 and then slowly raised from the melt 114. As the seed crystal 122 is slowly raised from the melt 114, atoms from the melt 114 align themselves with and attach to the seed crystal 122 to form the ingot 116.
The crystal pulling system 100 also includes a multi-stage cooling system 200 (broadly, a temperature control system) configured to control the cooling rate of the ingot 116 as the ingot is pulled from the melt 114. As described in more detail herein, the multi-stage cooling system 200 enables controlled cooling of the ingot 116 as the ingot 116 is removed from the melt 114, and thereby facilities reducing and/or controlling lateral incorporation and nucleation of defects within ingot 116.
The housing 102 includes a lower portion 124, an upper dome 126 connected to the lower portion 124, and an elongate tubular portion 128 extending generally upward from the upper dome 126. The growth chamber 104 is defined by the lower portion 124 and the upper dome 126, and the ingot removal chamber 106 is generally defined by the elongate tubular portion 128. The upper dome 126 includes a central annular opening 130 through which the ingot 116 is pulled into the ingot removal chamber 106. The housing 102 may be made of stainless steel or other suitable materials. In some embodiments, one or more of the lower portion 124, the upper dome 126, and the tubular portion 128 may include fluid-cooled (e.g., water-cooled) stainless steel walls.
The crucible 112 is positioned within the growth chamber 104 and beneath the removal chamber 106 such that the ingot 116 can be pulled by the crystal pulling mechanism 118 through the central opening 130 in the upper dome 126 and into the removal chamber 106. The crucible 112 may be made of, for example, quartz or any other suitable material that enables the crystal pulling system 100 to function as described herein. Further, the crucible 112 may have any suitable size that enables the crystal pulling system 100 to function as described herein. In some embodiments, the crucible has a diameter of between about 500 millimeters (mm) and about 1080 mm.
The pulling mechanism 118 generally includes a pull cable 132, a seed holder or chuck 134 connected to one end of pull cable 132, and the seed crystal 122 secured to the seed holder or chuck 134 for initiating crystal growth. The pull cable 132 is connected to a suitable lift or motor to pull the pull cable 132, along with the crystal chuck 134, the seed crystal 122, and the ingot 116, generally upward along a pull axis 136. The pulling mechanism 118 is also configured to rotate the seed crystal 122 to facilitate uniform crystal growth.
The heating elements 120 are configured to melt an initial charge of solid feedstock (such as chunk polysilicon), and maintain the melt 114 in a liquefied state after the initial charge is melted. The heating elements are arranged at suitable locations about the crucible 112. In the illustrated embodiment, one of the heating elements 120 is positioned beneath the crucible 112 and the susceptor 108, and another heating element 120 is positioned around a sidewall of the crucible 112. In the illustrated embodiment, each heating element 120 has a generally annular shape, although the heating elements 120 may have any suitable shape that enables the crystal pulling system 100 to function as described herein. In the example embodiment, the heating elements 120 are resistive heaters, although the heating elements 120 may be any suitable heating device that enables the system 100 to function as described herein. Further, while the illustrated embodiment is shown and described as including two heating elements 120, the system 100 may include any suitable number of heating elements that enables the system 100 to function as described herein.
The crystal pulling system 100 also includes a controller 138 communicatively connected to various components of the system 100, including the heating elements 120, the pulling mechanism 118, and the rotatable shaft 110 (or a motor (not shown) connected to the shaft 110). The controller 138 controls electric current supplied to the heating elements 120 to control the amount of thermal energy supplied by the heating elements 120. The controller 138 also controls operation of the pulling mechanism 118 and the rotatable shaft 110. In particular, the controller 138 is configured to control a pull rate of the pulling mechanism 118, a rotation rate of the seed crystal 122, and a rotation rate of the shaft 110.
The crystal pulling system 100 may also include one or more sensors (not shown), such as a pyrometer or like temperature sensor, to provide continuous or intermittent measurements of the temperature of the melt 114 at the melt/crystal interface of the growing single crystal ingot 116. The sensors may be communicatively connected with controller 138 to provide feedback information about the growth process to the controller.
As shown in
The heat shield 202 is positioned and oriented to reflect heat radiated by the ingot 116 (and other components of the crystal pulling system 100) back towards the ingot 116 through the gap 214.
With additional reference to
The inner reflector 218 and the outer reflector 220 are constructed of suitable heat reflective materials. Suitable materials from which the inner reflector 218 and the outer reflector 220 may be constructed include, for example and without limitation, graphite, silicon carbide coated graphite, and high purity molybdenum. The inner reflector 218 may be constructed of the same material as the outer reflector 220, or the inner and outer reflectors 218, 220 may be constructed of different materials.
The insulating layer 216 is constructed of a material having low thermal conductivity, and is contained within an insulation chamber 224 defined between the inner reflector 218 and the outer reflector 220 to insulate the inner reflector 218 against heat transfer from the outer reflector 220 to the inner reflector 218.
The multi-stage cooling jacket 204 is mounted on the crystal puller housing 102 adjacent the bottom of the removal chamber 106 and extends down into the growth chamber 104 and into the elongate passage 206 defined by the heat shield 202. As noted above, the cooling jacket 204 includes a cylindrical fluid-cooled housing 208 having a top or upper portion 210 spaced vertically from a bottom or lower portion 212 by an annular gap 214 defined by the housing 208. As described in more detail herein, the gap 214 between the upper portion 210 and the lower portion 212 reduces the cooling rate (i.e., decreases the rate of cooling) of the ingot 116 as the ingot 116 is pulled through the cooling system 200, thereby providing multiple different cooling zones arranged vertically along the pull axis 136.
The lower portion 212 of the housing 208 is spaced a sufficient distance 226 from the melt 114 to enable a flow of purge gas between the melt 114 and the lower portion 212 of the housing without creating surface disruptions in the surface of the melt 114. In some embodiments, the distance 226 between the lower portion 212 of the housing 208 and the melt 114 may be minimal to enable rapid cooling of the ingot 116 as it is pulled from the melt 114. In some embodiments, the distance 226 between the lower portion 212 of the housing 208 and the melt 114 is in the range of about 30 mm to about 70 mm.
The upper and lower portions 210, 212 of the cooling jacket housing 208 may be connected to one another by one or more bridges or interconnecting members (not shown) extending from the upper portion 210 to the lower portion 212. The size of the gap 214 (i.e., the vertical spacing or length 228 between the upper portion 210 and the lower portion 212) is selected based on, among other things, the size of the ingot 116, the temperature profile within the growth chamber 104, and the pull rate of the ingot 116. The gap 214 is sized to provide a zone of reduced cooling over a temperature range between the solidification temperature of the ingot 116 and a nucleation temperature of defects incorporated into the ingot. The gap is sized to provide sufficient time for diffusion of vacancies or other impurities incorporated into the ingot 116, thereby allowing incorporated defects to be more evenly distributed and reducing localized high concentration regions of defects, such as near the lateral surface of the ingot 116. In some embodiments, the gap 214 has a size (i.e., vertical length 228) of between about 50 mm and about 200 mm.
Other dimensions of the cooling jacket 204 and the cooling system 200 may also be based on the size of the ingot 116, the temperature profile within the growth chamber 104, and/or the pull rate of the ingot 116. In some embodiments, the vertical length 230 of the upper portion 210 of the housing 208 is between about 250 mm and about 500 mm. Further, in some embodiments, the cooling jacket 204 is spaced from the heat shield 202 by a radial distance or spacing 232 of between about 0 mm and about 200 mm.
In the illustrated embodiment, the lower portion 212 of the housing 208 has a square cross-section, and the upper portion 210 of the housing 208 has a rectangular cross-section. In other suitable embodiments, the housing 208, including the upper portion 210 and the lower portion 212, may have any suitable cross-sectional shape that enables the cooling jacket 204 to function as described herein. Referring to
Referring again to
The cooling tube 240 is fluidly connected to a suitable cooling fluid source, such as water, via a conduit (not shown) to receive cooling fluid into the cooling jacket 204. The interior chamber 238 of the cooling jacket housing 208 is fluidly connected to an outlet or exhaust port (not shown) via a conduit (not shown) to exhaust cooling fluid from the cooling jacket 204.
As shown in
The cooling jacket 204 may also include one or more baffles (not shown) within the interior chamber 238 to direct cooling fluid exhausted from the cooling tube 240 to desired portions of the cooling jacket 204, such as the lower portion 212 of the cooling jacket housing 208, or towards an outlet port of the cooling jacket housing 208.
In the example embodiment, the cooling jacket 204, including the housing 208 and the cooling tube 240, are constructed of steel, although the cooling jacket 204 may be constructed from materials other than steel. Further, the cooling tube 240 may have a construction other than a helical coil construction, such as by being formed as an annular ring (not shown) or other plenum structure (not shown) that circumscribes all or part of the inner panel 234 of the cooling jacket housing 208.
In operation of the cooling jacket 204, cooling fluid is received into the cooling jacket 204 from the cooling fluid source via a suitable conduit (not shown), and flows downward through the cooling tube 240 within the interior chamber 238 of the cooling jacket housing 208. With the cooling tube 240 in close contact relationship with the inner panel 234 of the housing 208, conductive heat transfer occurs between the inner panel 234 and the cooling fluid in the cooling tube 240 to cool the inner panel 234. When cooling fluid reaches the lowermost turn of the cooling tube 240, it flows out of the cooling tube 240 and is directed downward into the lower portion 212 of the housing 208. The cooling fluid then flows around the lower portion 212 of the housing 208, and back upward beneath the lowermost turn of the cooling tube 240 in a direction opposite the direction that cooling fluid flows downward through the cooling tube. As a result, cooling fluid flows back up through the interior chamber 238 of the housing 208 generally within the spacing between the turns of the cooling tube 240. Cooling fluid flows out from the housing 208 via an exhaust or outlet port (not shown).
The configuration of the cooling system 200, and more particularly, the cooling jacket 204, results in a plurality of different cooling zones being defined vertically along the pull axis 136 of the crystal pulling system 100. In the illustrated embodiment, the cooling system 200 (specifically, the cooling jacket 204) defines a first cooling zone 242 along the lower portion 212 of the housing 208, a second cooling zone 244 between the lower portion 212 and upper portion 210 of the housing 208 (i.e., coextensive with the gap 214), and a third cooling zone 246 along the upper portion 210 of the housing 208. The first cooling zone 242 has an enhanced or relatively high cooling rate, and may be used to “quench” or rapidly cool the ingot 116 (or an axial segment thereof) to a temperature below a solidification temperature of the ingot 116, such as about 1100° C. for silicon. Suitable cooling rates for the first cooling zone include, for example and without limitation, cooling rates in the range of about 2° C./minute to about 4° C./minute. The second cooling zone 244 has a reduced or relatively low cooling rate, and may be used to slowly cool the ingot 116 (or an axial segment thereof) from a temperature below the solidification temperature of the ingot 116 (e.g., 1100° C.) down to a nucleation temperature (e.g., 900° C.) of defects incorporated into the ingot 116. Suitable cooling rates for the second cooling zone include, for example and without limitation, cooling rates in the range of about 0.5° C./minute to about 1.5° C./minute. The third cooling zone 246 has an enhanced or relatively high cooling rate, and may be used to rapidly cool the ingot 116 (or an axial segment thereof) from a temperature at or near a defect nucleation temperature (e.g., 900° C.) to a temperature below the defect nucleation temperature (e.g., 600° C.). Suitable cooling rates for the third cooling zone include, for example and without limitation, cooling rates in the range of about 1.5° C./minute to about 2.5° C./minute. The first and third cooling zones 242, 246 are interchangeably referred to herein as enhanced-rate cooling zones due the enhanced cooling effect of the cooling jacket 204. The second cooling zone 244 is interchangeably referred to herein as a reduced-rate cooling zone due to the reduced or diminished cooling rate of the ingot 116 resulting from heat being reflected by the heat shield 202 back towards the ingot 116 through the gap 214 within the second cooling zone, as described in more detail herein.
The configuration of the cooling system 200, such as the heat shield 202 and the cooling jacket 204, may vary without departing from some aspects of this disclosure.
In the above-described cooling systems, the components of the cooling systems are arranged to provide generally the same thermal or cooling cycle of the ingot as the ingot is pulled from the melt. The particular arrangement of the components may vary based on practical implementation considerations, including ease of assembly, cost of components, and lifetime of components due to aging, cracking, damage, etc. In general, components having a thinner radial span will have a lower overall radial temperature gradient, and, consequently, less thermal stress.
Without being bound by any particular theory, it is believed that the arrangement of multiple different cooling zones of the cooling systems described herein facilitates reducing the size and concentration of defects grown in to the defect edge band of the ingot 116. In particular, it is believed that by initially rapidly cooling or quenching the ingot to solidify the ingot near the melt, the concentration of vacancies initially incorporated into the ingot at the initial stage of crystal growth will be reduced. Because the lateral incorporation of vacancies and other defects establishes the initial excess defect concentration near the edge of the crystal being grown in a CZ process, fewer defects are available to agglomerate to form large defects. Further, by slowly cooling the ingot from the solidification temperature to a temperature at or around a defect nucleation temperature, it is believed that vacancies and other defects incorporated into the ingot near the lateral edge will diffuse radially inward, thereby allowing incorporated defects to be more evenly distributed and reducing localized high concentration regions of defects near the lateral surface of the ingot. Further, it is believed that rapidly cooling the ingot through defect nucleation temperatures inhibits or “freezes” the growth of voids and oxygen precipitates, thereby reducing the average size of agglomerated defects in the grown-in edge band of the ingot.
Referring again to
As the ingot 116 is pulled through the multi-stage cooling system 200, the ingot 116 is cooled at different cooling rates. More specifically, an axial segment of the ingot is cooled at at least three different cooling rates as the axial segment is pulled through the cooling system 200. In particular, the axial segment is cooled at a first, initial cooling rate as the ingot 116 is pulled through the lower portion 212 of the housing 208 and the first cooling zone 242. The initial cooling rate is a relatively high cooling rate and “quenches” or rapidly solidifies the ingot 116 to reduce vacancy incorporation and concentration at the initial stages of crystal growth.
The axial segment is cooled at a second cooling rate less than the first cooling rate as the ingot 116 is pulled past the lower portion 212 of the housing 208 and through the second cooling zone 244 adjacent the gap 214. When the axial segment is positioned within the second cooling zone 244, heat radiated by the ingot 116 (and other portions of the crystal pulling system 100) is reflected back towards the ingot 116 through the gap 214 by the heat shield 202. The reflected heat causes the ingot (specifically, the axial segment within the second cooling zone 244) to cool more slowly than in the first cooling zone 242 and the third cooling zone 246. The reduced cooling rate facilities diffusion of vacancies and/or other impurities incorporated into the ingot, thereby allowing incorporated defects to be more evenly distributed and reducing localized high concentration regions of defects, such as near the lateral surface of the ingot.
As the axial segment of the ingot 116 is pulled past the second cooling zone 244 and into the upper portion 210 of the housing 208 and the third cooling zone 246, the axial segment is cooled at a third cooling rate greater than the second cooling rate. The third cooling rate is a relatively high cooling rate and facilities reducing or inhibiting growth of agglomerated defects below the associated defect nucleation temperature by limiting the thermal energy available for diffusion and nucleation.
In one embodiment, the method of growing a monocrystalline ingot may further include controlling one or more process parameters of the growth process to control the profile of the melt/crystal interface of the ingot based on a desired or target melt/crystal interface profile. In particular, use of the multi-stage cooling systems described herein results in a hot zone configuration (i.e. the heater, insulation, heat shield(s), cooling jacket, and radiation shield(s), among other things) different than hot zone configurations in previously used crystal pulling systems. As a result, the thermal profile within the growth chamber is different, which impacts the thermal gradient in the core of the ingot as well as the profile of the melt/crystal interface. Because the profile of the melt/crystal interface affects lateral incorporation of vacancies during crystal growth, a new target melt/crystal interface profile may be determined based on the new hot zone configuration in order to further reduce or minimize the size and/or concentration of defects grown into the defect edge band.
As shown in
The target melt/crystal interface profile for an ingot may be determined, for example, based on the hot zone configuration of the crystal pulling system, as well as a desired defect concentration profile and/or an average defect size profile. Because the hot zone configuration also affects the defect concentration profile and the average defect size profile of grown ingots, an iterative approach may be used to arrive at a desired or optimal hot zone configuration and a target melt/crystal interface profile.
Once the target melt/crystal interface profile is determined, one or more process parameters of the growth process may be controlled based on the target melt/crystal interface profile. Referring to
Embodiments of the crystal pulling systems described herein may also include one or more gas flow guides or barriers to control and/or inhibit the flow of gas within certain portions of the crystal pulling system. In some embodiments, for example, the crystal pulling system 100 may include a gas flow barrier to prevent or inhibit the flow of oxide species evaporated from the melt (e.g., SiO and SiO2) to areas around the cooling jacket 204, such as between the cooling jacket 204 and the heat shield 202. Such gas flow barriers may improve the Czochralski growth process by reducing the rate of particulate deposition on the cooling jacket 204 and, consequently, reducing the likelihood of particulate shedding and loss of CZ crystal structure. In particular, because the surfaces of the cooling jacket 204 are relatively cool as compared to other surfaces within the hot zone, gases evaporated from the melt during the crystal growth process, such as silicon oxide species (i.e., SiOx species), tend to deposit more quickly on the cooling jacket as compared to other portions of the crystal pulling system 100. As the thickness of these deposits increase, the likelihood of particulate shedding and loss of CZ crystal structure also increases. Embodiments of gas flow barriers described herein may improve the Czochralski crystal growth process by reducing the rate of particulate deposition on the cooling jacket and, consequently, reducing the likelihood of particulate shedding and loss of CZ crystal structure.
As shown in
Further, in the example embodiment, the gas flow barrier 1104 extends between the lower portion 212 of the cooling jacket 204 and the melt 114 (shown in
In the example embodiment, the gas flow barrier 1104 includes a plate 1120 having a general frusto-conical or frusto-spherical shape. In other embodiments, the gas flow barrier 1104 may have any suitable construction and shape that enables the gas flow barrier 1104 to function as described herein. In some embodiments, the gas flow barrier 1104 is formed integrally with the heat shield 1106. That is, the gas flow barrier 1104 is formed as a single, unitary piece with the heat shield 1106. In other embodiments, the gas flow barrier 1104 is formed separately and connected to the heat shield 1106 with suitable fastening means (e.g., adhesives or mechanical fasteners). Suitable materials from which the gas flow barrier 1104 may be constructed include, for example and without limitation, graphite, silicon carbide coated graphite, and high purity molybdenum.
In the example embodiment, the gas flow barrier 1104 includes a first, radial outer portion 1122 and a second, radial inner portion 1124. Each of the radial outer portion 1122 and the radial inner portion 1124 is substantially planar. The radial outer portion 1122 extends radially inward and downward from the heat shield 1106 at a first oblique angle 1126, and the radial inner portion 1124 extends radially inward form the radial outer portion 1122 at a second oblique angle 1128.
The radial outer portion 1122 and the radial inner portion 1124 may have any suitable thicknesses that enable the gas flow barrier 1104 to function as described herein. In the example embodiment, the radial outer portion 1122 has a substantially uniform thickness 1130, and the radial inner portion 1124 has a thickness 1132 that continuously decreases towards a radial inner end 1134 of the gas flow barrier 1104. In some embodiments, the thickness 1130 of the radial outer portion 1122 is between 4 mm and 12 mm, such as between 4 mm and 8 mm, between 5 mm and 9 mm, between 6 mm and 10 mm, between 7 mm and 11 mm, or between 8 mm and 12 mm. In some embodiments, the thickness 1132 of the radial inner portion 1124 at the radial inner end 1134 is between 2 mm and 10 mm, such as between 2 mm and 6 mm, between 3 mm and 7 mm, between 4 mm and 8 mm, between 5 mm and 9 mm, or between 6 mm and 10 mm.
In the example embodiment, the size or height of the opening 1116 defined by the gas flow barrier 1104 and the cooling jacket 204 gradually and continuously decreases along the direction of gas flow (i.e., in the radial outward direction). In other words, the size or height 1136 of the opening 1116 at the radial outer side of the cooling jacket 204 is smaller than the size or height 1138 of the opening 1116 at the radial inner side of the cooling jacket. In some embodiments, the height 1136 of the opening 1116 at the radial outer side of the cooling jacket 204 is between 5 mm and 13 mm, such as between about 5 mm and 9 mm, between 6 mm and 10 mm, between 7 mm and 11 mm, between 8 mm and 12 mm, or between 9 mm and 13 mm. In some embodiments, the height 1138 of the opening 1116 at the radial inner side of the cooling jacket 204 is between 9 mm and 17 mm, such as between 9 mm and 13 mm, between 10 mm and 14 mm, between 11 mm and 15 mm, between 12 mm and 16 mm, or between 13 mm and 17 mm.
As shown in
The systems and methods described herein are suitable for use in growing a variety of different types and sizes of monocrystalline ingots. The systems and methods described herein are particularly suitable for growing ingots having a diameter of between about 150 mm to about 450 mm, and having an initial feedstock charge size of between about 150 kilograms (kg) and about 450 kg. Ingots having diameters less than 150 mm or greater than 450 mm, or charge sizes other than between about 150 kilograms (kg) and about 450 kg may also be grown using the systems and methods disclosed herein. Further, the systems and methods described herein are suitable for use in growing nitrogen-doped crystal ingots. The nitrogen concentration of ingots grown using the systems and methods described herein may range from 0 cm−3 to about 1×1015 cm−3.
Embodiments of the crystal pulling systems and methods described herein provide several advantages over known crystal pulling systems and methods. In particular, embodiments described facilitate reducing the size and concentration of defects that form the grown-in defect edge band in monocrystalline ingots grown by the Czochralski method, such as single crystal silicon ingots. In particular, some systems and methods described facilitate reducing the concentration and/or the size of defects incorporated into the crystal ingot during growth by reducing and/or controlling the lateral incorporation and transport of defects, such as vacancies and oxygen impurities, as the crystal ingot is grown from a melt. Embodiments described may also facilitate reducing the size of defects in crystal ingots by reducing and/or controlling the nucleation of agglomerated defects, such as voids and oxygen precipitates, as the crystal ingot is grown. Also, these embodiments may facilitate reducing and/or controlling lateral incorporation and nucleation of defects by controlling the cooling rate of the ingot and by controlling the profile of the melt/crystal interface during growth of the crystal. Some systems and methods described use a multi-stage cooling system that subjects the ingot to multiple different cooling rates as the ingot is pulled from the melt. Use of the multi-stage cooling system facilitates precisely controlling the various transport and nucleation mechanisms of defects at various stages of crystal growth, and thereby facilitates reducing the size and/or concentration of defects incorporated into the crystal during growth. Moreover, the present disclosure provides a method for determining a desired or target melt/crystal interface profile for reducing and/or controlling lateral incorporation of defects, and for controlling process parameters during crystal growth to achieve the desired melt/crystal interface profile.
Additionally, embodiments of the crystal pulling systems and methods described facilitate reducing particulate deposition within the crystal pulling system by controlling and/or inhibiting the flow of gas within certain portions of the crystal pulling system. Some embodiments, for example, include a gas flow barrier that inhibits the flow of SiO-containing gas to between a cooling jacket and a heat shield of the multi-stage cooling system that may otherwise result in excessive SiO deposits along the cooling jacket.
When introducing elements of the present invention or the embodiment(s) thereof, the articles “a”, “an”, “the” and “said” are intended to mean that there are one or more of the elements. The terms “comprising”, “including” and “having” are intended to be inclusive and mean that there may be additional elements other than the listed elements.
As various changes could be made in the above constructions and methods without departing from the scope of the invention, it is intended that all matter contained in the above description and shown in the accompanying drawings shall be interpreted as illustrative and not in a limiting sense.
Claims
1. A crystal pulling system for growing a monocrystalline ingot from a melt of semiconductor or solar-grade material, the system comprising:
- a crucible for containing the melt of semiconductor or solar-grade material;
- a pulling mechanism configured to pull the ingot from the melt along a pull axis; and
- a multi-stage heat exchanger defining a central passage for receiving the ingot as the ingot is pulled by the pulling mechanism, wherein the heat exchanger defines a plurality of cooling zones arranged vertically along the pull axis of the crystal pulling system, wherein the plurality of cooling zones includes two enhanced-rate cooling zones and a reduced-rate cooling zone disposed vertically between the two enhanced-rate cooling zones.
2. The crystal pulling system of claim 1, wherein the pulling mechanism includes a seed crystal connected to a pull cable configured to raise and lower the seed crystal and to rotate the seed crystal about the pull axis, the system further comprising a controller configured to control a melt/crystal interface profile by controlling a rate of rotation of the seed crystal.
3. The crystal pulling system of claim 1 further comprising a heat shield disposed radially outward from the heat exchanger, the heat shield defining an elongate passage for receiving the ingot as the ingot is pulled from the melt, wherein the heat exchanger is positioned within the passage defined by the heat shield.
4. The crystal pulling system of claim 3, wherein the heat exchanger includes a cylindrical fluid-cooled housing having an upper portion and a lower portion spaced vertically from the upper portion by an annular gap, and wherein the heat shield is positioned and oriented to reflect heat towards the ingot through the gap.
5. The crystal pulling system of claim 3, wherein the heat shield includes insulation.
6. The crystal pulling system of claim 3, wherein the heat shield includes a radiation shield.
7. The crystal pulling system of claim 3, further comprising a gas flow barrier extending under the heat exchanger and between the heat exchanger and the melt such that an annular opening is defined between the gas flow barrier and the heat exchanger.
8. The crystal pulling system of claim 7, wherein the gas flow barrier is connected to a lower end of the heat shield and extends radially inward from the heat shield and under the heat exchanger.
9. The crystal pulling system of claim 7, wherein the gas flow barrier occludes the heat exchanger from a direct vertical line-of-sight with the melt.
10. The crystal pulling system of claim 1, wherein the heat exchanger includes a cylindrical fluid-cooled housing having an upper portion and a lower portion spaced vertically from the upper portion by an annular gap, and wherein the lower portion of the housing defines a first enhanced-rate cooling zone, the upper portion of the housing defines a second enhanced-rate cooling zone, and a reduced-rate cooling zone is defined between the lower portion of the housing and the upper portion of the housing.
11. The crystal pulling system of claim 10, wherein the first enhanced-rate cooling zone has a first cooling rate, the reduced-rate cooling zone has a second cooling rate less than the first cooling rate, and the second enhanced-rate cooling zone has a third cooling rate greater than the second cooling rate.
12. The crystal pulling system of claim 10, wherein the heat exchanger includes a quartz baffle disposed proximate the gap defined by the housing, the quartz baffle configured to inhibit gas flow through the gap.
Type: Application
Filed: Jul 16, 2021
Publication Date: Nov 4, 2021
Inventors: Soubir Basak (Chandler, AZ), Gaurab Samanta (Brentwood, MO), Parthiv Daggolu (Creve Coeur, MO), Benjamin Michael Meyer (Defiance, MO), William L. Luter (St. Charles, MO), Jae Woo Ryu (Chesterfield, MO), Eric Michael Gitlin (St. Peters, MO)
Application Number: 17/378,251