An embodiment of the present invention provides a heat shield device for low oxygen single crystal growth of a single crystal ingot growth device, including: a crucible containing a silicon melt; a graphite crucible surrounding the crucible; a heat shield made of a low-emissivity (emissivity<0.3) material that surrounds a central lower portion of the graphite crucible and is spaced apart from the graphite crucible by a predetermined distance; and a connection part connecting the heat shield and the graphite crucible. Through the heat shield device according to the first embodiment of the present invention and the heat shield coating according to the second embodiment of the present invention, the concentration of oxygen flowing into the crystal may be reduced by lowering the temperature of the bottom of the crucible during the crystal growth, and the yield may be improved by reducing the BMD concentration in the semiconductor device through the growth of high-quality and low-oxygen single crystal.

The present application provides an apparatus and a method for ingot growth. The apparatus for ingot growth comprises a growth furnace, a crucible, a heater, a lifting mechanism, an infrared detector, a dividing disc, a sensor and a control device. The crucible is located within the growth furnace. The lifting mechanism comprises a lifting wire and a driving device, wherein the lifting wire connects to the top of the ingot via one terminal and to the driving device via another terminal. The bottom of the ingot puts inside the crucible, and the ingot has plural crystal lines thereon. The infrared detector is located outside the growth furnace. The dividing disc is above the growth furnace, connects to the lifting mechanism, and rotates with the ingot synchronously under the driving of the lifting mechanism, and an orthographic projection of bisector of the dividing disc is between two adjacent crystal lines. The sensor is located on the periphery of the dividing disc. The control device connects to the infrared detector and the sensor in order to control the infrared detector to detect the ingot diameter while the sensor senses the bisector of the dividing disc. The present application is able to increase ingot quality and enhance product yield.

The present application provides an apparatus and a method for ingot growth. The apparatus for ingot growth comprises a growth furnace, a crucible, a heater, a lifting mechanism, an infrared detector, a dividing disc, a sensor and a control device. The crucible is located within the growth furnace. The lifting mechanism comprises a lifting wire and a driving device, wherein the lifting wire connects to the top of the ingot via one terminal and to the driving device via another terminal. The bottom of the ingot puts inside the crucible, and the ingot has plural crystal lines thereon. The infrared detector is located outside the growth furnace. The dividing disc is above the growth furnace, connects to the lifting mechanism, and rotates with the ingot synchronously under the driving of the lifting mechanism, and an orthographic projection of bisector of the dividing disc is between two adjacent crystal lines. The sensor is located on the periphery of the dividing disc. The control device connects to the infrared detector and the sensor in order to control the infrared detector to detect the ingot diameter while the sensor senses the bisector of the dividing disc. The present application is able to increase ingot quality and enhance product yield.

A method for producing a silicon ingot includes withdrawing a seed crystal from a melt that includes melted silicon in a crucible that is enclosed in a vacuum chamber containing a cusped magnetic field. At least one process parameter is regulated in at least two stages, including a first stage corresponding to formation of the silicon ingot up to an intermediate ingot length, and a second stage corresponding to formation of the silicon ingot from the intermediate ingot length to the total ingot length. During the second stage process parameter regulation may include reducing a crystal rotation rate, reducing a crucible rotation rate, and/or increasing a magnetic field strength relative to the first stage.

A method for producing a silicon ingot includes withdrawing a seed crystal from a melt that includes melted silicon in a crucible that is enclosed in a vacuum chamber containing a cusped magnetic field. At least one process parameter is regulated in at least two stages, including a first stage corresponding to formation of the silicon ingot up to an intermediate ingot length, and a second stage corresponding to formation of the silicon ingot from the intermediate ingot length to the total ingot length. During the second stage process parameter regulation may include reducing a crystal rotation rate, reducing a crucible rotation rate, and/or increasing a magnetic field strength relative to the first stage.

Disclosed a heat shield device for a single crystal production furnace. The heat shield device is disposed above a melt crucible of the single crystal production furnace, and comprises a shell, supporting members, heat insulation plates and a direction control component. The supporting members and the heat insulation plates are disposed within of the shell. One end of the supporting member is fixedly connected with an inner wall of the shell. The direction control component is connected with the heat insulation plate. The supporting members serve as supporting points of the heat insulation plates, and cooperate with the direction control component to control rotation of the heat insulation plates relative to the shell. A rotatable angle of the heat insulation plate faces a cylindrical surface of monocrystalline silicon, and a bottom surface of the shell faces interior of the melt crucible.

Disclosed a heat shield device for a single crystal production furnace. The heat shield device is disposed above a melt crucible of the single crystal production furnace, and comprises a shell, supporting members, heat insulation plates and a direction control component. The supporting members and the heat insulation plates are disposed within of the shell. One end of the supporting member is fixedly connected with an inner wall of the shell. The direction control component is connected with the heat insulation plate. The supporting members serve as supporting points of the heat insulation plates, and cooperate with the direction control component to control rotation of the heat insulation plates relative to the shell. A rotatable angle of the heat insulation plate faces a cylindrical surface of monocrystalline silicon, and a bottom surface of the shell faces interior of the melt crucible.

The present invention relates to an apparatus for growing a single crystal ingot capable of uniformly controlling an oxygen concentration in a longitudinal direction and a radial direction of a single crystal ingot by uniformly maintaining a convection pattern on a silicon melt interface, and a method for growing the same. In an apparatus for growing a single crystal ingot and a method for growing the same according to the present invention, a horizontal magnet is positioned to be movable up and down by a magnet moving unit around a crucible, so that a maximum gauss position (MGP) is positioned to be higher than the silicon melt interface and simultaneously, a rate of increase in the MGP is controlled to 3.5 mm/hr to 6.5 mm/hr, and thus it possible to secure simplicity and symmetry of convection on the silicon melt interface. Accordingly, in the present invention, it is possible to reduce an Oi deviation and a BMD deviation in a longitudinal direction and a radial direction of a single crystal ingot, thereby improving quality.

The present invention relates to an apparatus for growing a single crystal ingot capable of uniformly controlling an oxygen concentration in a longitudinal direction and a radial direction of a single crystal ingot by uniformly maintaining a convection pattern on a silicon melt interface, and a method for growing the same. In an apparatus for growing a single crystal ingot and a method for growing the same according to the present invention, a horizontal magnet is positioned to be movable up and down by a magnet moving unit around a crucible, so that a maximum gauss position (MGP) is positioned to be higher than the silicon melt interface and simultaneously, a rate of increase in the MGP is controlled to 3.5 mm/hr to 6.5 mm/hr, and thus it possible to secure simplicity and symmetry of convection on the silicon melt interface. Accordingly, in the present invention, it is possible to reduce an Oi deviation and a BMD deviation in a longitudinal direction and a radial direction of a single crystal ingot, thereby improving quality.

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.