A method of manufacturing a reverse-blocking IGBT (insulated gate bipolar transistor) includes forming a plurality of IGBT cells in a device region of a semiconductor substrate, forming a reverse-blocking edge termination structure in a periphery region of the semiconductor substrate which surrounds the device region, etching one or more trenches in the periphery region between the reverse-blocking edge termination structure and a kerf region of the semiconductor substrate, depositing a p-type dopant source which at least partly fills the one or more trenches and diffusing p-type dopants from the p-type dopant source into semiconductor material surrounding the one or more trenches, so as to form a continuous p-type doped region in the periphery region which extends from a top surface of the semiconductor substrate to a bottom surface of the semiconductor substrate after thinning of the semiconductor substrate at the bottom surface.

A method for manufacturing a substrate wafer 100 includes providing a device wafer (110) having a first side (111) and a second side (112); subjecting the device wafer (110) to a first high temperature process for reducing the oxygen content of the device wafer (110) at least in a region (112a) at the second side (112); bonding the second side (112) of the device wafer (110) to a first side (121) of a carrier wafer (120) to form a substrate wafer (100); processing the first side (101) of the substrate wafer (100) to reduce the thickness of the device wafer (110); subjecting the substrate wafer (100) to a second high temperature process for reducing the oxygen content at least of the device wafer (110); and at least partially integrating at least one semiconductor component (140) into the device wafer (110) after the second high temperature process.

Methods of forming doped elements of semiconductor device structures include forming trenches having undercut portions separating stem portions of a substrate. The stem portions extend between a base portion of the substrate and overlying broader portions of the substrate material. A carrier material including a dopant is formed at least on the sides of the stems in the undercut portions of the trenches. The dopant is diffused from the carrier material into the stems. As such, the narrow stem portions of the substrate become doped with a targeted dopant-delivery method. The doped stems may form or be incorporated within buried, doped, conductive elements of semiconductor device structures, such as digit lines of memory arrays. Also disclosed are related semiconductor device structures.

A first contact hole is formed so as to extend to a NiSi layer as a lower wiring conductor layer connecting to an N+ layer of an SGT formed within a Si pillar, and so as to extend through a NiSi layer as an upper wiring conductor layer connecting to a gate TiN layer, and a NiSi layer as an intermediate wiring conductor layer connecting to an N+ layer. A second contact hole is formed so as to extend to the NiSi layer, and surround, in plan view, the first contact hole. An insulating SiO2 layer is formed on a side surface of the NiSi layer. A wiring metal layer in the contact holes connects the NiSi layer and the NiSi layer to each other.

A method of forming a transistor can include forming a gate mask on a substrate having a vertical location aligned with that of a transistor control gate; implanting first conductivity type dopants with the gate mask as an implant mask to form a first shallow halo region; implanting first conductivity type dopants with at least the gate mask as an implant mask to form a first deep halo region having a peak dopant concentration profile at a greater substrate depth than the first shallow halo region; forming an epitaxial layer on top of the substrate; forming a first control gate structure on the epitaxial layer; and forming a first source or drain region, of a second conductivity type, in at least the epitaxial layer to a side of the first control gate, and over the first shallow halo region and the first deep halo region.

A method for doping fins includes depositing a first dopant layer at a base of fins formed in a substrate, depositing a dielectric layer on the first dopant layer and etching the dielectric layer and the first dopant layer in a first region to expose the substrate and the fins. A second dopant layer is conformally deposited over the fins and the substrate in the first region. The second dopant layer is recessed to a height on the fins in the first region. An anneal is performed to drive dopants into the fins from the first dopant layer in a second region and from the second dopant layer in the first region to concurrently form punch through stoppers in the fins and wells in the substrate.

A method for doping a substrate is provided. A silicon oxide diffusion barrier layer is formed on a surface of the substrate. At least one dopant layer is deposited over the silicon oxide diffusion barrier layer. A cap layer is deposited over the at least one dopant layer forming a stack of the substrate, the silicon oxide diffusion layer, the at least one dopant layer, and the cap layer. The stack is annealed. The cap layer, at least one dopant layer, and the silicon oxide diffusion barrier layer are removed.

A method for forming a doped zone of a transistor includes providing a stack having at least one active layer made from a semiconductor material, and a transistor gate pattern having at least one lateral side, and modifying a portion of the active layer so as to form a modified portion made of a modified semiconductor material. The modified portion extends down to the at least one lateral side of the gate pattern, at the edge of a non-modified portion above which the gate pattern is located. The method also includes forming a spacer on the lateral side, removing the modified portion by selective etching of the modified semiconductor material with respect to the semiconductor material of the non-modified portion, so as to expose an edge of the non-modified portion, and forming the doped zone by epitaxy starting from the exposed edge.

A 3D memory device includes a memory stack including interleaved stack conductive layers and stack dielectric layers, a semiconductor layer, and a channel structure extending vertically through the memory stack into the semiconductor layer. A first lateral dimension of a first portion of the channel structure facing the semiconductor layer is greater than a second lateral dimension of a second portion of the channel structure facing the memory stack. The channel structure includes a memory film and a semiconductor channel A first doping concentration of part of the semiconductor channel in the first portion of the channel structure is greater than a second doping concentration of part of the semiconductor channel in the second portion of the channel structure.

Methods of doping a semiconductor material are disclosed. Some embodiments provide for conformal doping of three dimensional structures. Some embodiments provide for doping with high concentrations of boron for p-type doping.