The field relates to systems and methods for producing a single crystal silicon ingot using a vaporized dopant.
In high resistivity silicon wafer applications, the resistivity of the single crystal silicon ingot from which the wafers are sliced may be controlled by addition of various dopants to the melt. The dopants may be used to compensate for various impurities (e.g., boron or phosphorous) in the source of polycrystalline silicon used to form a melt from which the silicon ingot is withdrawn.
When one or more dopants are added to achieve a target resistivity in the ingot, certain dopants and/or impurities may accumulate in the melt due to differences in the segregation coefficients of the compounds. For example, boron has a segregation coefficient of about 0.8 which allows boron to be readily taken up into the growing ingot. Phosphorous has a segregation coefficient of about 0.35 which causes phosphorous to accumulate in the melt relative to boron which is taken up more readily. Accordingly, as the ingot grows and the melt is depleted, phosphorous accumulates in the melt altering the resistivity of the growing ingot. This can cause the resistivity to decrease and fall out of customer specifications and/or for a type-change to occur in the ingot.
A need exists for methods for counter-doping a silicon melt during ingot growth to increase the length of the ingot that remains within customer specifications. A need also exists for doping methods that allow for use of dopant source materials that are readily available and/or relatively inexpensive and that allow the melt to be doped with relative ease. Further, an ingot puller apparatus that allows a liquid-phase dopant to be used as the source of dopant is needed.
This section is intended to introduce the reader to various aspects of art that may be related to various aspects of the 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.
In one aspect, an ingot puller apparatus for producing a doped single crystal silicon ingot includes a housing defining a chamber, a crucible disposed within the chamber, and a dopant injector extending into the housing. The dopant injector includes a delivery module attached to and extending through the housing into the chamber. The delivery module includes a dopant injection tube positioned within the chamber and a vaporization cup positioned within the dopant injection tube and the chamber. The second valve selectively channels the liquid dopant into the vaporization cup and the vaporization cup vaporizes the liquid dopant into a vaporized dopant.
In another aspect, an ingot puller apparatus for producing a doped single crystal silicon ingot includes a housing defining a chamber, a crucible disposed within the chamber, and a dopant injector extending into the housing. The dopant injector includes an injection module attached to an outer surface of the housing. The injection module includes a first reservoir for containing a liquid dopant, a second reservoir for containing the liquid dopant, a first valve for selectively channeling the liquid dopant from the first reservoir to the second reservoir, and a second valve for selectively channeling the liquid dopant from the second reservoir to the chamber. The dopant injector also includes a delivery module attached to the injection module and extending through the housing into the chamber. The second valve selectively channels the liquid dopant into the delivery module and the delivery module vaporizes the liquid dopant into a vaporized dopant.
In yet another aspect, an ingot puller apparatus for producing a doped single crystal silicon ingot includes a housing defining a chamber, a crucible disposed within the chamber, and a dopant injector extending into the housing. The dopant injector includes an injection module attached to an outer surface of the housing. The injection module includes a first reservoir for containing a liquid dopant, a second reservoir for containing the liquid dopant, a first valve for selectively channeling the liquid dopant from the first reservoir to the second reservoir, and a second valve for selectively channeling the liquid dopant from the second reservoir to the chamber. The dopant injector also includes a delivery module attached to the injection module and extending through the housing into the chamber. The delivery module includes a dopant injection tube positioned within the chamber and a vaporization cup positioned within the dopant injection tube and the chamber. The second valve selectively channels the liquid dopant into the vaporization cup and the vaporization cup vaporizes the liquid dopant into a vaporized dopant.
Various refinements exist of the features noted in relation to the above-mentioned aspects of the present disclosure. Further features may also be incorporated in the above-mentioned aspects of the present disclosure 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 of the present disclosure may be incorporated into any of the above-described aspects of the present disclosure, alone or in any combination.
Corresponding reference characters indicate corresponding parts throughout the drawings.
An example ingot puller apparatus 100 is generally shown in
Referring now to
The ingot puller apparatus 100 includes a dopant injector 114 for injecting liquid dopant into the ingot puller apparatus as the ingot 110 is pulled from the silicon melt 108. The dopant injector 114 enables the silicon melt 108 to be counter-doped with a liquid dopant multiple times as the ingot 110 is pulled from the melt, increasing the resistivity of the ingot, increasing the portion of the ingot that is within customer specifications (e.g., high resistivity), and increasing the efficiency of the ingot puller apparatus.
The dopant injector 114 includes an injection module 116, a delivery module 118, and a first flange 120. The injection module 116 and the delivery module 118 are each attached to the first flange 120, and the flange attaches the injection module and the delivery module to the housing 102. Specifically, the housing 102 defines a dopant injector opening 122, and the first flange 120 is attached to the housing such that the flange covers the dopant injector opening.
The injection module 116 is attached to a first side 124 of the first flange 120 such that the injection module is positioned outside the chamber 104. The delivery module 118 is attached to a second side 126 of the first flange 120 such that the delivery module is positioned within the chamber 104. The injection module 116 receives dopant and channels the dopant to the delivery module 118, and the delivery module receives dopant from the injection module and injects the dopant into the chamber 104 as described herein. In this embodiment, the injection module 116 receives a liquid dopant, and the delivery module 118 vaporizes the liquid dopant within the chamber 104 as described herein.
As shown in
The cooling fluid conduits 134 and 136 include a cooling fluid supply 134 and a cooling fluid return 136. The cooling fluid conduits 134 and 136 extend through the actuation mechanism 132 and into the doping chamber 130. The actuation mechanism 132 includes air cylinders 150 for actuating valves within the dopant injector 114 as described herein. The ports 140, 142, and 144 include an inert gas port 140 for supplying an inert gas to the dopant injector 114, a pressure sensor port 142 for measuring a pressure of the doping chamber 130, and a vacuum port 144 for generating a vacuum within the doping chamber.
As shown in
The dopant addition tube 152 is coupled to the first reservoir 156, and the first valve 162 is selectively actuated by the actuation shaft 168 to maintain or release liquid dopant within the first reservoir. The dopant addition tube 152 receives liquid dopant and channels the liquid dopant to the first reservoir 156. The first valve 162 is closed and maintains the liquid dopant within the first reservoir 156. Upon actuation by the actuation shaft 168, the first valve 162 opens and channels the liquid dopant into the second reservoir 160 as described herein.
The first reservoir 156 is coupled to the second reservoir 160, and the first valve 162 is selectively actuated by the actuation shaft 168 to release liquid dopant within the first reservoir to the second reservoir. The second reservoir 160 receives liquid dopant and channels the liquid dopant to the delivery module 118. The second valve 164 is closed and maintains the liquid dopant within the second reservoir 160. Upon actuation by the actuation shaft 168, the second valve 164 opens and channels the liquid dopant into the delivery module 118 as described herein. The cooling jacket 170 receives a cooling fluid from the cooling fluid supply 134 and returns the cooling fluid to the cooling fluid return 136. The cooling fluid cools the injection module 116 to prevent the injection module from overheating.
The ingot puller inner chamber 104 is maintained at a first pressure, and the doping chamber 130 is maintained at a second pressure greater than the first pressure. Specifically, the first pressure of the ingot puller inner chamber 104 is maintained at a vacuum, and the second pressure of the doping chamber 130 is maintained at atmospheric pressure such that the liquid dopant is also maintained at atmospheric pressure. In alternative embodiments, the first pressure of the ingot puller inner chamber 104 is maintained at a pressure below atmospheric pressure, and the second pressure of the doping chamber 130 is maintained at a pressure above the first pressure. Accordingly, the liquid dopant is maintained at the second pressure (atmospheric pressure) until the liquid dopant is injected into the ingot puller inner chamber 104 where the pressure of the liquid dopant is reduced to the first pressure (a vacuum).
The actuator 166 is positioned within the doping chamber 130 and is coupled to the air cylinders 150 and the actuation shaft 168. The air cylinders 150 actuate the actuator 166, and the actuator 166 actuates the first valve 162 and the actuation shaft 168. The actuation shaft 168 actuates the second valve 164. More specifically, in the illustrated embodiment, the actuator 166 is a linear actuator that translates the first valve 162 and the shaft 168 linearly to translate open the first valve and to translate the second valve 164 linearly to open the second valve. In alternative embodiments, the actuation shaft 168 is coupled to both the first valve 162 and the second valve 164 and actuates both the first valve and the second valve. In some embodiments, the actuation shaft 168 independently actuates the first valve 162 and the second valve 164. In alternative embodiments, the actuation shaft 168 actuates the first valve 162 and the second valve 164 simultaneously. For example, the actuation shaft 168 may actuate the first valve 162 and the second valve 164 simultaneously such that the first valve 162 is closed when the second valve 164 is open and the first valve 162 is open when the second valve 164 is closed in order to maintain the first pressure within the ingot puller inner chamber 104.
The delivery module 118 includes a feed tube 172 and a vaporization cup 174 positioned within the feed tube. The feed tube 172 is positioned within the ingot puller inner chamber 104 and channels vaporized dopant to the silicon melt 108. Specifically, the vaporization cup 174 is heated by radiant heat from within the ingot puller inner chamber 104 and receives the liquid dopant from the second reservoir 160. The ingot puller apparatus 100 includes a heating system 176 that melts the silicon melt 108 and radiates heat into the ingot puller inner chamber 104. The liquid dopant is vaporized into a vaporized dopant within the ingot puller inner chamber 104 where the liquid dopant is vaporized by flash evaporation by heating the liquid dopant with the vaporization cup 174 and reducing the pressure of the liquid dopant from the second pressure to the first pressure by injecting the liquid dopant into the ingot puller inner chamber 104.
The feed tube 172 has a distal end 178 furthest from the ingot puller outer housing 102 and a proximal end 180 nearest the ingot puller outer housing. A feed tube axis A extends through the distal end 178 and the proximal end 180 of the feed tube 172. The feed tube 172 may be made of quartz or other suitable materials.
The feed tube 172 is moveable within the ingot puller inner chamber 104 along the feed tube axis A. The feed tube 172 may be lowered into the ingot puller inner chamber 104 toward the silicon melt 108. Specifically, the feed tube 172 is attached to the cooling jacket 170, and the cooling jacket is attached to the doping chamber 130. The bellows 138 enables the doping chamber 130, the cooling jacket 170, and the feed tube 172 to move along the feed tube axis A toward and away from the silicon melt 108. By moving the doping chamber 130, the cooling jacket 170, and the feed tube 172, the distal end 178 of the feed tube 172 moves between a raised position in which the distal end positioned away from the silicon melt 108 and a lowered position in which the distal end is positioned proximate the surface of the silicon melt 108. The heat shield 112 may include a channel 182 formed therein to provide a pathway for the feed tube 172 to approach the silicon melt 108.
In the lowered position of the feed tube 172, the vaporized dopant travels down the feed tube where it is directed to the surface of the silicon melt 108. The vaporized dopant passes through the distal end 178 of the feed tube 172 to contact the silicon melt 108 to cause the silicon melt to be doped and/or counter doped. As the doping chamber 130, the cooling jacket 170, and the feed tube 172 are moved from the raised position to the lower position, the distance between the vaporization cup 174 and the silicon melt 108 and the heating system 176 may be changed (e.g., by an operator).
The vaporization cup 174 includes a receiver 184 and a vaporization plug 186 positioned within the receiver and divides the receiver into a liquid reception portion 188 and a vapor channel portion 190. The receiver 184 and the vaporization plug 186 define the liquid reception portion 188, and the receiver 184 defines channels 192 that channel vaporized dopant from the liquid reception portion to the feed tube 172. The vaporization plug 186 has a first end 194 and a second end 196 and defines vaporization channels 198 extending from the first end to the second end that channel vaporized dopant from the liquid reception portion 188 to the vapor channel portion 190.
Excess heat from the heating system 176 heats the vaporization plug 186, and the second valve 164 channels the liquid dopant from the second reservoir 160 into the liquid reception portion 188 and onto the vaporization plug. The vaporization plug 186 vaporizes the liquid dopant into vaporized dopant by flash evaporation by heating the liquid dopant with the vaporization plug 186 and reducing the pressure of the liquid dopant from the second pressure to the first pressure by injecting the liquid dopant into the liquid reception portion 188. The vaporization channels 198 channel the vaporized dopant into the channels 192 of the vapor channel portion 190 which channel the vaporized dopant into the feed tube 172 and to the silicon melt 108. Additionally, a process gas (e.g., argon) may be circulated through the doping chamber 130 through the inert gas port 140 for channeling the vaporized dopant through the vaporization cup 174 and the feed tube 172.
The pressure sensor port 142 enables measurement of the pressure within the ingot puller inner chamber 104. The vacuum port 144 enables pump-down and leak testing. The cooling jacket 170 cools the injection module 116 to prevent the injection module from overheating
Example methods of the present disclosure are shown in
With reference to
To prepare the silicon melt, polycrystalline silicon is added to the crucible 106. The polycrystalline silicon is heated to above the melting temperature of silicon (about 1414° C.) to cause the polycrystalline silicon to liquefy into the silicon melt 108. The heating system 176 is operated to melt-down the polycrystalline silicon. For example, one or more heaters 200 below or to the side of the crucible 106 are operated to melt-down the silicon.
Before or after the melt 108 is produced, the melt may be doped with a dopant, typically an n-type dopant, to compensate for p-type impurities (e.g., boron) in the melt. The n-type dopant may be added before growth of the ingot 110 commences. By compensating the melt, the resistivity of the resulting ingot 110 may be increased. For example, the seed end of the ingot (i.e., the portion of the ingot nearest the ingot crown) may have a resistivity of at least about 30 Ω-cm or, as in other embodiments, at least about 35 Ω-cm, at least about 40 Ω-cm, at least about 45 Ω-cm, at least about 50 Ω-cm, at least about 55 Ω-cm, at least about 60 Ω-cm or from about 30 Ω-cm to about 60 ohm-cm. Suitable n-type dopants include phosphorous and arsenic.
Once the melt 108 is prepared, the single crystal silicon ingot 110 is pulled from the melt 108. A seed crystal 202 is secured to a seed chuck 204. The seed chuck 204 and seed crystal 202 are lowered until the seed crystal 202 contacts the surface of the silicon melt 108. Once the seed crystal 202 begins to melt, a pulling mechanism slowly raises the seed crystal 202 up to grow the monocrystalline ingot 110. A process gas (e.g., argon) is circulated through the ingot puller inner chamber 104 of the ingot puller apparatus 100. The process gas creates an atmosphere within the ingot puller inner chamber 104.
Embodiments of methods of the present disclosure include providing a source of liquid-phase boric acid (H3BO3). The boric acid may be relatively pure such as about 99% pure or more, 99.9% pure or more, or 99.99% pure or more. In some embodiments, the boric acid may be relatively isotopically pure (i.e., boron-11).
A boron-containing gas is produced from the liquid-phase boric acid. The gas that is produced is generally in the form of boric acid (H3BO3) or derivatives thereof (BxOyHz+ complexes) and not other compounds (e.g., diborane (B2H6) or boron dihydride (BH2)). However, it should be understood that other boron compounds may be added to the boron-containing gas.
The liquid-phase boric acid may be heated to above its vaporization temperature (about 300° C.) to produce a boron-containing gas. For example, the liquid-phase boric acid may be heated by heat radiated from the silicon melt 108 in the ingot puller apparatus 100 or by the heating system 176.
Once the boron-containing gas is produced, the boron-containing gas contacts the surface of the silicon melt 108 to allow boron to diffuse into the melt. Once boron enters the melt, boron compensates for phosphorous which has concentrated in the melt due to the relatively low segregation coefficient of phosphorous, thereby increasing the resistivity of the remaining portion of the ingot 110 that forms in the ingot puller apparatus 100.
Compared to conventional methods for producing a single crystal silicon ingot from a silicon melt, the systems and methods of the present disclosure have several advantages. Specifically, a larger portion of the ingot may be within customer specifications (e.g., high resistivity) and/or a type-change in the ingot may be prevented. More specifically, the systems and methods of the present disclosure control the rate of doping such that compensating boron is incorporated into the ingot to neutralize the effect of segregation by phosphorous. Thus, the net free charge carriers may be maintained between limits over the length of the ingot. Depending on the target resistivity of the ingot, controlling the rate of doping may prevent a type change of the ingot from n-type to p-type or in other examples, from p-type to n-type. Liquid-phase boric acid has a relatively low vaporization temperature which allows a dopant gas to be produced with relative ease. Additionally, the vaporization cup may be placed within ingot puller housing which allows the heat of the melt and the heating system to vaporize the dopant. The feed tube is moveable within the ingot puller apparatus such that the distance from the melt may be controlled which allows the rate of dopant addition to the melt to be controlled. Accordingly, the systems and methods described herein increases the efficiency of the ingot puller apparatus by counter-doping the silicon melt multiple times during production of the ingot and maintaining the resistivity of a larger portion of the ingot within customer specifications (e.g., high resistivity).
As used herein, the terms “about,” “substantially,” “essentially” and “approximately” when used in conjunction with ranges of dimensions, concentrations, temperatures or other physical or chemical properties or characteristics is meant to cover variations that may exist in the upper and/or lower limits of the ranges of the properties or characteristics, including, for example, variations resulting from rounding, measurement methodology or other statistical variation.
When introducing elements of the present disclosure 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,” “containing” and “having” are intended to be inclusive and mean that there may be additional elements other than the listed elements. The use of terms indicating a particular orientation (e.g., “top”, “bottom”, “side”, etc.) is for convenience of description and does not require any particular orientation of the item described.
As various changes could be made in the above constructions and methods without departing from the scope of the disclosure, it is intended that all matter contained in the above description and shown in the accompanying drawing[s] shall be interpreted as illustrative and not in a limiting sense.
This application is a continuation of and claims priority to U.S. patent application Ser. No. 17/139,367, filed on Dec. 31, 2020, the disclosure of which is incorporated by reference in its entirety.
Number | Date | Country | |
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Parent | 17139367 | Dec 2020 | US |
Child | 18464790 | US |