Methods for producing a single crystal silicon ingot are disclosed. The ingot is doped with boron using solid-phase boric acid as the source of boron. Boric acid may be used to counter-dope the ingot during ingot growth. Ingot puller apparatus that use a solid-phase dopant are also disclosed. The solid-phase dopant may be disposed in a receptacle that is moved closer to the surface of the melt or a vaporization unit may be used to produce a dopant gas from the solid-phase dopant.

A monocrystalline silicon includes a shoulder, a straight body, and a tail. The straight body includes: a first straight body having a first diameter d1; and a second straight body provided closer to the shoulder than the first straight body is and having a second diameter d2 larger than the first diameter d1 by from 3.5% to 15%. Firstly, a resistivity at a start point of the straight body connected to the shoulder is set to a first resistivity. Subsequently, the monocrystalline silicon is pulled up and grown to form the first straight body, and a resistivity at a start point of the first straight body is set to a second resistivity lower than the first resistivity.

A monocrystalline silicon includes a shoulder, a straight body, and a tail. The straight body includes: a first straight body having a first diameter d1; and a second straight body provided closer to the shoulder than the first straight body is and having a second diameter d2 larger than the first diameter d1 by from 3.5% to 15%. Firstly, a resistivity at a start point of the straight body connected to the shoulder is set to a first resistivity. Subsequently, the monocrystalline silicon is pulled up and grown to form the first straight body, and a resistivity at a start point of the first straight body is set to a second resistivity lower than the first resistivity.

Crystal pulling systems having composite polycrystalline silicon feed tubes, methods for forming such tubes, and methods for forming a single crystal silicon ingot with use of such tubes. The composite polycrystalline silicon feed tubes include quartz and at least one dopant. The composite polycrystalline silicon feed tube may be made by a slip cast method.

Crystal pulling systems having composite polycrystalline silicon feed tubes, methods for forming such tubes, and methods for forming a single crystal silicon ingot with use of such tubes. The composite polycrystalline silicon feed tubes include quartz and at least one dopant. The composite polycrystalline silicon feed tube may be made by a slip cast method.

A semiconductor wafer including a single crystal doped with a dopant, wherein a resistivity of the wafer is 0.7 mΩ-cm or less, and wherein a striation height of the wafer is 6 mm or more. The resistivity of the wafer may be 0.8 mΩ-cm or less, and the striation height may be 13 mm or more. The resistivity of the wafer may be 0.7 mΩ-cm or less, and the striation may be 22 mm or more. Example features relate to a method of making a semiconductor wafer that includes adding a dopant to a silicon melt, rotationally pulling a crystal from the silicon melt, and applying a magnetic field of 3000 G or more such that the semiconductor wafer has a resistivity that is equal to or less than 0.8 mΩ-cm and a striation height that is equal to or more than 13 mm.

A semiconductor wafer including a single crystal doped with a dopant, wherein a resistivity of the wafer is 0.7 mΩ-cm or less, and wherein a striation height of the wafer is 6 mm or more. The resistivity of the wafer may be 0.8 mΩ-cm or less, and the striation height may be 13 mm or more. The resistivity of the wafer may be 0.7 mΩ-cm or less, and the striation may be 22 mm or more. Example features relate to a method of making a semiconductor wafer that includes adding a dopant to a silicon melt, rotationally pulling a crystal from the silicon melt, and applying a magnetic field of 3000 G or more such that the semiconductor wafer has a resistivity that is equal to or less than 0.8 mΩ-cm and a striation height that is equal to or more than 13 mm.

Methods for producing a single crystal silicon ingot are disclosed. The ingot is doped with boron using solid-phase boric acid as the source of boron. Boric acid may be used to counter-dope the ingot during ingot growth. Ingot puller apparatus that use a solid-phase dopant are also disclosed. The solid-phase dopant may be disposed in a receptacle that is moved closer to the surface of the melt or a vaporization unit may be used to produce a dopant gas from the solid-phase dopant.

Methods for producing a single crystal silicon ingot are disclosed. The ingot is doped with boron using solid-phase boric acid as the source of boron. Boric acid may be used to counter-dope the ingot during ingot growth. Ingot puller apparatus that use a solid-phase dopant are also disclosed. The solid-phase dopant may be disposed in a receptacle that is moved closer to the surface of the melt or a vaporization unit may be used to produce a dopant gas from the solid-phase dopant.

Methods for producing single crystal silicon ingots are disclosed. The methods may involve modeling formation of thermal donors and target resistivity during downstream annealing processes such as during subsequent device manufacturing such as manufacturing of interposer devices. The model may output a pre-anneal wafer resistivity target range. The single crystal silicon ingot production process may be modeled to determine a counter-doping schedule to achieve the pre-anneal wafer resistivity target range across a longer length of the main body of the ingot.