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.

A manufacturing method of a monocrystalline silicon includes: a growth step in which a seed crystal having contacted a silicon melt is pulled up and a crucible is rotated and raised to form a straight body of the monocrystalline silicon; a separating step in which the monocrystalline silicon is separated from the silicon melt; a state holding step in which the crucible and the monocrystalline silicon are lowered and the monocrystalline silicon is kept at a level at which an upper end of the straight body is located at the same level as an upper end of a heat shield or is located below the upper end of the heat shield for a predetermined time; and a draw-out step in which the monocrystalline silicon is drawn out of a chamber.

A manufacturing method of a monocrystalline silicon includes: a growth step in which a seed crystal having contacted a silicon melt is pulled up and a crucible is rotated and raised to form a straight body of the monocrystalline silicon; a separating step in which the monocrystalline silicon is separated from the silicon melt; a state holding step in which the crucible and the monocrystalline silicon are lowered and the monocrystalline silicon is kept at a level at which an upper end of the straight body is located at the same level as an upper end of a heat shield or is located below the upper end of the heat shield for a predetermined time; and a draw-out step in which the monocrystalline silicon is drawn out of a chamber.

An embodiment provides a silicon supply part including: a silicon supply chamber; a holder provided on an inner wall of a lower region of the silicon supply chamber; a tube elevating vertically by a first cable inside the silicon supply chamber; a guide provided outside the tube and overlapped with the holder vertically; and a stopper elevating vertically by a second cable and inserted into a lower portion of the tube to open and close the lower portion of the tube.

An embodiment provides a silicon supply part including: a silicon supply chamber; a holder provided on an inner wall of a lower region of the silicon supply chamber; a tube elevating vertically by a first cable inside the silicon supply chamber; a guide provided outside the tube and overlapped with the holder vertically; and a stopper elevating vertically by a second cable and inserted into a lower portion of the tube to open and close the lower portion of the tube.

A single crystal pulling apparatus including: a remelting detection apparatus which detects that remelting of a lower end portion of the semiconductor single crystal is completed from a change in weight of the semiconductor single crystal when the lower end portion of the semiconductor single crystal is immersed in the melt to be remolten by using the wire; and a lowermost end detection apparatus which detects a lowermost end of the semiconductor single crystal from a position where no current flows between the semiconductor single crystal and the melt when the semiconductor single crystal is taken up with the use of the wire while applying a voltage between the semiconductor single crystal and the melt by applying a voltage between the crucible and the wire.

A single crystal pulling apparatus including: a remelting detection apparatus which detects that remelting of a lower end portion of the semiconductor single crystal is completed from a change in weight of the semiconductor single crystal when the lower end portion of the semiconductor single crystal is immersed in the melt to be remolten by using the wire; and a lowermost end detection apparatus which detects a lowermost end of the semiconductor single crystal from a position where no current flows between the semiconductor single crystal and the melt when the semiconductor single crystal is taken up with the use of the wire while applying a voltage between the semiconductor single crystal and the melt by applying a voltage between the crucible and the wire.

A silicon single crystal growing apparatus based on a Czochralski method arranges a graphite crucible inside a graphite heater for heating and a quartz crucible inside the graphite crucible and grows a crystal from a raw material melt filling the quartz crucible, and includes a heater outer heat-insulating member outside the graphite heater, a crucible lower heat-insulating member below the graphite crucible, a crucible upper heat-insulating member above straight bodies of the graphite and quartz crucibles, a crucible outer heat-insulating member outside the straight body of the graphite crucible, a crucible inner heat-insulating member inside the straight bodies of the graphite crucible and the quartz crucible, and a heat shielding member above a liquid surface of the raw material melt, the graphite crucible and the quartz crucible being movable upward and downward in a space enclosed with the crucible upper heat-insulating, crucible outer heat-insulating, and crucible inner heat-insulating members.

A silicon single crystal growing apparatus based on a Czochralski method arranges a graphite crucible inside a graphite heater for heating and a quartz crucible inside the graphite crucible and grows a crystal from a raw material melt filling the quartz crucible, and includes a heater outer heat-insulating member outside the graphite heater, a crucible lower heat-insulating member below the graphite crucible, a crucible upper heat-insulating member above straight bodies of the graphite and quartz crucibles, a crucible outer heat-insulating member outside the straight body of the graphite crucible, a crucible inner heat-insulating member inside the straight bodies of the graphite crucible and the quartz crucible, and a heat shielding member above a liquid surface of the raw material melt, the graphite crucible and the quartz crucible being movable upward and downward in a space enclosed with the crucible upper heat-insulating, crucible outer heat-insulating, and crucible inner heat-insulating members.