The invention relates to a method for manufacturing a semiconductor-on-insulator structure (10), comprising the following steps: —providing an FD-SOI substrate (1) comprising, successively from its base to its top: a monocrystalline substrate (2) having an electrical resistivity of between 500 Ω.Math.cm and 30 kΩ.Math.cm, an interstitial oxygen content (Oi) of between 20 and 40 old ppma, and having an N- or P-type doping, an electrically insulating layer (3) having a thickness of between 20 nm and 400 nm, a monocrystalline layer (4) having a P-type doping, —heat-treating the FD-SOI substrate (1) at a temperature greater than or equal to 1175° C. for a time greater than or equal to 1 hour in order to form a P-N junction (5) in the substrate. The invention also relates to such a semiconductor-on-insulator 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.

A semiconductor device includes a semiconductor body having a first surface. A first trench extends in a vertical direction into the semiconductor body. The semiconductor device also includes a first interlayer in the first trench and a first dopant source in the first trench. The first interlayer is arranged between the first dopant source and the semiconductor body, and the first dopant source includes a first dopant species. The semiconductor device also includes a semiconductor area doped with the first dopant species and which completely surrounds the first trench at least at a depth in the semiconductor body and adjoins the first trench.

The present invention relates to a process for the production of structured, highly efficient solar cells and of photovoltaic elements which have regions of different doping. The invention likewise relates to the solar cells having increased efficiency produced in this way.

An example system includes a processing circuit coupled to a memory system and an interface coupled between the processing circuit and a device. The memory system includes a resistive memory array comprising multiple memory structures. Each memory structure comprises a resistive memory cell and is associated with a P-I-N diode. The processing circuit is to access the resistive memory array responsive to a signal received from the device via the interface.

A semiconductor device includes a semiconductor substrate having a first region and a second region, a plurality of first semiconductor fins in the first region, a plurality of second semiconductor fins in the second region, a first solid-state dopant source layer within the first region on the semiconductor substrate, a first insulating buffer layer on the first solid-state dopant source layer, a second solid-state dopant source layer within the second region on the semiconductor substrate, a second insulating buffer layer on the second solid-state dopant source layer and on the first insulating buffer layer, a first fin bump in the first region, and a second fin bump in the second region. The first fin bump includes a first sidewall spacer and the second fin bump comprises a second sidewall spacer. The first sidewall spacer has a structure that is different from that of the second sidewall spacer.

A method for manufacturing a semiconductor device includes forming a fin structure having a top surface and side surfaces. A mask layer is disposed over the top surface. A doping support layer is formed to cover part of the fin structure. A first impurity is introduced into a first region of the fin structure covered by the doping support layer, by implanting the first impurity into the doping support layer so that the implanted first impurity is introduced into the first region of the fin structure through the side surfaces.

A method is provided for manufacturing a memory device. A strip of semiconductor material is formed having a memory region, a contact landing area region and a switch region between the memory region and the contact landing area region. A memory layer is formed on surfaces of the strip in the memory region. A plurality of memory cell gates is formed over the memory region of the strip. A switch gate is formed over the switch region of the strip. A doped insulating material is deposited over a portion of the strip between the contact landing area region and the memory region. Diffusion of dopant is caused from the doped insulating material into the strip in the portion of the strip.

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 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.