Ingot puller apparatus having a heat shield disposed below a side heater and methods for preparing an ingot in such ingot puller apparatus are disclosed. In some embodiments, the side heater is relatively short. The side heater may be fully above a floor of the crucible when the crucible is in its lowest position in the ingot puller.

Ingot puller apparatus having a heat shield disposed below a side heater and methods for preparing an ingot in such ingot puller apparatus are disclosed. In some embodiments, the side heater is relatively short. The side heater may be fully above a floor of the crucible when the crucible is in its lowest position in the ingot puller.

A method for growing a single crystal silicon ingot by the continuous Czochralski method is disclosed. The melt depth and thermal conditions are constant during growth because the silicon melt is continuously replenished as it is consumed, and the crucible location is fixed. The critical v/G is determined by the hot zone configuration, and the continuous replenishment of silicon to the melt during growth enables growth of the ingot at a constant pull rate consistent with the critical v/G during growth of a substantial portion of the main body of the ingot. The continuous replenishment of silicon is accompanied by periodic or continuous nitrogen addition to the melt to result in a nitrogen doped ingot.

A method for growing a single crystal silicon ingot by the continuous Czochralski method is disclosed. The melt depth and thermal conditions are constant during growth because the silicon melt is continuously replenished as it is consumed, and the crucible location is fixed. The critical v/G is determined by the hot zone configuration, and the continuous replenishment of silicon to the melt during growth enables growth of the ingot at a constant pull rate consistent with the critical v/G during growth of a substantial portion of the main body of the ingot. The continuous replenishment of silicon is accompanied by periodic or continuous nitrogen addition to the melt to result in a nitrogen doped ingot.

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.

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.

Disclosed a heat shield structure for a single crystal production furnace, which is provided above a melt crucible of a single crystal production furnace and comprises an outer housing and a heat insulation plate disposed within the outer housing. A bottom outer surface of the outer housing faces an interior of the melt crucible, and an angle formed between a plane in which the heat insulation plate is located and a plane in which a bottom of the outer housing is located is an acute angle and faces an outer surface of single crystal silicon. The heat shield design is changed, a heat absorbing plate is additionally provided for transferring heat absorbed to the single crystal silicon, a heat channel is formed in the heat shield, so that a pulling rate is controlled, which improves radial mass uniformity of the single crystal silicon.

Disclosed a heat shield structure for a single crystal production furnace, which is provided above a melt crucible of a single crystal production furnace and comprises an outer housing and a heat insulation plate disposed within the outer housing. A bottom outer surface of the outer housing faces an interior of the melt crucible, and an angle formed between a plane in which the heat insulation plate is located and a plane in which a bottom of the outer housing is located is an acute angle and faces an outer surface of single crystal silicon. The heat shield design is changed, a heat absorbing plate is additionally provided for transferring heat absorbed to the single crystal silicon, a heat channel is formed in the heat shield, so that a pulling rate is controlled, which improves radial mass uniformity of the single crystal silicon.