Gated MIS tunnel diode devices having a controllable negative transconductance behavior are provided. In some embodiments, a device includes a substrate, a tunnel diode dielectric layer on a surface of the substrate, and a gate dielectric layer on the surface of the substrate and adjacent to the tunnel diode dielectric layer. A tunnel diode electrode is disposed on the tunnel diode dielectric layer, and a gate electrode is disposed on the gate dielectric layer. A substrate electrode is disposed on the surface of the substrate, and the tunnel diode electrode is positioned between the gate electrode and the substrate electrode.

After the various regions of a vertical power device are formed in or on the top surface of an n-type wafer, the wafer is thinned, such as by grinding. A drift layer may be n-type, and various n-type regions and p-type regions in the top surface contact a top metal electrode. A blanket dopant implant through the bottom surface of the thinned wafer is performed to form an n− buffer layer and a bottom p+ emitter layer. Energetic particles are injected through the bottom surface to intentionally damage the crystalline structure. A wet etch is performed, which etches the damaged crystal at a much greater rate, so some areas of the n− buffer layer are exposed. The bottom surface is metallized. The areas where the metal contacts the n− buffer layer form cathodes of an anti-parallel diode for conducting reverse voltages, such as voltage spikes from inductive loads.

A microelectronic device including an analog MOS transistor. The analog transistor has a body well having a first conductivity type in a semiconductor material of a substrate of the microelectronic device. The body well extends deeper in the substrate than a field relief dielectric layer at the top surface of the semiconductor material. The analog transistor has a drain well and a source well having a second, opposite, conductivity type in the semiconductor material, both contacting the body well. The drain well and the source well extend deeper in the substrate than the field relief dielectric layer. The analog transistor has a gate on a gate dielectric layer over the body well. The drain well and the source well extend partway under the gate at the top surface of the semiconductor material.

A method for making a quantum device including: forming, over a semiconductor layer, a graphoepitaxy guide forming a cavity with a lateral dimension that is a multiple of a period of self-assembly of a di-block copolymer into lamellas; first deposition of the copolymer in the cavity; first self-assembly of the copolymer, forming a first alternating arrangement of first lamellas and of second lamellas; removal of the first lamellas; implantation of dopants in portions of the semiconductor layer previously covered with the first lamellas; removal of the second lamellas; second deposition of the copolymer in the cavity, over a gate material; second self-assembly of the copolymer, forming a second alternating arrangement of first and second lamellas; removal of the second lamellas; etching of portions of the gate material previously covered with the second lamellas.

A method of fabricating a device includes providing a fin element in a device region and forming a dummy gate over the fin element. In some embodiments, the method further includes forming a source/drain feature within a source/drain region adjacent to the dummy gate. In some cases, the source/drain feature includes a bottom region and a top region contacting the bottom region at an interface interposing the top and bottom regions. In some embodiments, the method further includes performing a plurality of dopant implants into the source/drain feature. In some examples, the plurality of dopant implants includes implantation of a first dopant within the bottom region and implantation of a second dopant within the top region. In some embodiments, the first dopant has a first graded doping profile within the bottom region, and the second dopant has a second graded doping profile within the top region.

Embodiments of the present disclosure provide a semiconductor structure and a manufacturing method thereof. The method includes: providing a substrate, wherein the substrate includes a word line region, a bit line region, and a capacitive region arranged adjacently; forming a first stacked structure that covers a surface of the substrate, wherein the first stacked structure includes a first sacrificial layer located on the surface of the substrate and a first semiconductor layer located on a surface of the first sacrificial layer; forming a second stacked structure that covers a surface of the first stacked structure, wherein the second stacked structure includes a second sacrificial layer located on the surface of the first stacked structure and a second semiconductor layer located on a surface of the second sacrificial layer; and performing an ion implantation on the first semiconductor layer and the second semiconductor layer.

A semiconductor structure and a method for forming a semiconductor structure are provided. A sacrificial gate layer is removed to form a gate trench exposing a sacrificial dielectric layer. An ion implantation is performed to a portion of a substrate covered by the sacrificial dielectric layer in the gate trench. The sacrificial dielectric layer is removed to expose the substrate from the gate trench. An interfacial layer is formed over the substrate in the gate trench. A metal gate structure is formed over the interfacial layer in the gate trench.

A method for fabricating an integrated circuit is disclosed. The method comprises forming a semiconductor ridge over a semiconductor surface of a substrate and forming an implant screen on a top and sidewalls of the semiconductor ridge. The implant screen is at least two times thicker on the top of the semiconductor ridge relative to the sidewalls of the semiconductor ridge. The method further comprises implanting a dopant into the top and sidewalls of the semiconductor ridge.

A substrate for fabricating a MOSFET device includes a first epitaxial layer disposed on a silicon wafer. The silicon wafer is doped with a first dopant. A second epitaxial layer is disposed on the first epitaxial layer. An ion-implanted capping layer is disposed in the first epitaxial layer. The ion-implanted capping layer is doped with a second dopant. The first dopant has a diffusion coefficient in silicon higher than a diffusion coefficient of the second dopant in silicon. The ion-implanted capping layer is configured to limit up-diffusion of the first dopant from the silicon wafer into the second epitaxial layer.

Vertical etch heterolithic integrated circuit devices are described. A method of manufacturing NIP diodes is described in one example. A P-type substrate is provided, and an intrinsic layer is formed on the P-type substrate. An oxide layer is formed on the intrinsic layer, and one or more openings are formed in the oxide layer. One or more N-type regions are implanted in the intrinsic layer through the openings in the oxide layer. The N-type regions form cathodes of the NIP diodes. A dielectric layer deposited over the oxide layer is selectively etched away with the oxide layer to expose certain ranges of the intrinsic layer to define a geometry of the NIP diodes. The intrinsic layer and the P-type substrate are vertically etched away within the ranges to expose sidewalls of the intrinsic layer and the P-type substrate. The P-type substrate forms the anodes of the NIP diodes.