Abstract: A method for manufacturing a microelectronic device from a semiconductor-on-insulator substrate, the device having active components formed in active areas of the substrate separated by isolation trenches and which are delimited by first sidewalls, the isolation trenches being filled, at least partially, with a first dielectric material, includes a step of chemically attacking a passive section of the first bottom of the isolation trenches configured to generate, at said section, a roughness quadratic mean comprised between 2 nm and 6 nm. The method also includes a step of forming a passive component covering the first dielectric material and directly above the passive section.

Abstract: A semiconductor structure includes an isolation structure; first and second source/drain (S/D) features over the isolation structure, defining a first direction from the first S/D feature to the second S/D feature from a top view; one or more channel layers connecting the first and the second S/D features; a gate structure between the first and the second S/D features and engaging each of the one or more channel layers; and a via structure under the first S/D feature and electrically connecting to the first S/D feature. In a cross-sectional view perpendicular to the first direction, the via structure has a profile that widens and then narrows along a bottom-up direction.

Abstract: There is provided a semiconductor device including: an emitter region of a first conductivity type, a contact region of a second conductivity type, provided on the front surface side of the semiconductor substrate; one or more first trench portions which are electrically connected to a gate electrode and are in contact with emitter regions; a second trench portion which is adjacent to one of the one or more first trench portions, is electrically connected to the gate electrode, is in contact with the contact region of the second conductivity type, and is not in contact with the emitter region; and a dummy trench portion which is adjacent to one of the one or more first trench portions and is electrically connected to an emitter electrode, in which the contact region in contact with the second trench portion is in contact with the emitter electrode.

Abstract: A semiconductor structure is provided. The semiconductor structure includes a substrate, a diode region, and a dummy stripe. The substrate has a first surface. The diode region is in the substrate. The diode region includes a first implant region of a first conductivity type approximate to the first surface, and a second implant region of a second conductivity type approximate to the first surface and surrounded by the first implant region. The dummy stripe is on the first surface and located between the first implant region and the second implant region. A method for manufacturing a semiconductor structure is also provided.

Abstract: A semiconductor device includes a substrate including an active region, a gate structure disposed in a gate trench in the substrate, a bit line disposed on the substrate and electrically connected to the active region on one side of the gate structure, and a capacitor disposed on the bit line and electrically connected to the active region on another side of the gate structure. The gate structure includes a gate dielectric layer disposed on bottom and inner side surfaces of the gate trench, a conductive layer disposed on the gate dielectric layer in a lower portion of the gate trench, sidewall insulating layers disposed on the gate dielectric layer, on an upper surface of the conductive layer, a graphene conductive layer disposed on the conductive layer, and a buried insulating layer disposed between the sidewall insulating layers on the graphene conductive layer.

Abstract: The present disclosure describes a device that is protected from the effects of an oxide on the metal gate layers of ferroelectric field effect transistors. In some embodiments, the device includes a substrate with fins thereon; an interfacial layer on the fins; a crystallized ferroelectric layer on the interfacial layer; and a metal gate layer on the ferroelectric layer.

Abstract: A semiconductor device and method of manufacturing are provided. In an embodiment a first nucleation layer is formed within an opening for a gate-last process. The first nucleation layer is treated in order to remove undesired oxygen by exposing the first nucleation layer to a precursor that reacts with the oxygen to form a gas. A second nucleation layer is then formed, and a remainder of the opening is filled with a bulk conductive material.

Abstract: The present disclosure relates generally to structures in semiconductor devices and methods of forming the same. More particularly, the present disclosure relates to semiconductor devices having field plates that are arranged symmetrically around a gate. The present disclosure provides a semiconductor device including an active region above a substrate, source and drain electrodes in contact with the active region, a gate above the active region and laterally between the source and drain electrodes, a first field plate between the source electrode and the gate, a second field plate between the drain electrode and the gate, in which the gate is spaced apart laterally and substantially equidistant from the first field plate and the second field plate.

Abstract: A method of forming a metal oxide semiconductor field effect transistor with improved gate-induced drain leakage performance, the method including providing a semiconductor substrate having a gate trench formed therein, performing an ion implantation process on upper portions of sidewalls of the gate trench to make the upper portions more susceptible to oxidation relative to non-implanted lower portions of the sidewalls, and performing an oxidation process on surfaces of the substrate, wherein the implanted upper portions of the sidewalls develop a thicker layer of oxidation relative to the non-implanted lower portions of the sidewalls.

Abstract: A method for forming a semiconductor structure includes forming a fin structure over a substrate. The method also includes forming a gate structure across the fin structure. The method also includes depositing a dopant source layer over the gate structure. The method also includes driving dopants of the dopant source layer into the fin structure. The method also includes removing the dopant source layer. The method also includes annealing the dopants in the fin structure to form a doped region. The method also includes etching the doped region and the fin structure below the doped region to form a recess. The method also includes growing a source/drain feature in the recess.

Abstract: In an embodiment, a transistor device includes a semiconductor substrate having a main surface, a cell field including a plurality of transistor cells, and an edge termination region laterally surrounding the cell field. The cell field includes a gate trench in the main surface of the semiconductor substrate, a gate dielectric lining the gate trench, a metal gate electrode arranged in the gate trench on the gate dielectric, and an electrically insulating cap arranged on the metal gate electrode and within the gate trench.

Abstract: An embodiment is a method including forming a raised portion of a substrate, forming fins on the raised portion of the substrate, forming an isolation region surrounding the fins, a first portion of the isolation region being on a top surface of the raised portion of the substrate between adjacent fins, forming a gate structure over the fins, and forming source/drain regions on opposing sides of the gate structure, wherein forming the source/drain regions includes epitaxially growing a first epitaxial layer on the fin adjacent the gate structure, etching back the first epitaxial layer, epitaxially growing a second epitaxial layer on the etched first epitaxial layer, and etching back the second epitaxial layer, the etched second epitaxial layer having a non-faceted top surface, the etched first epitaxial layer and the etched second epitaxial layer forming source/drain regions.

Abstract: A method for forming a semiconductor structure is provided. The method includes forming a stack over a substrate. The stack includes alternating first semiconductor layers and second semiconductor layers. The method also includes forming a polishing stop layer over the stack and a dummy layer over the polishing stop layer, recessing the dummy layer, the polishing stop layer and the stack to form a recess, forming a third semiconductor layer to fill the recess, and planarizing the dummy layer and the third semiconductor layer until the polishing stop layer is exposed. The method also includes patterning the polishing stop layer and the stack into a first fin structure and the third semiconductor layer into a second fin structure, removing the second semiconductor layers of the first fin structure to form nanostructures, and forming a gate stack across the first fin structure and the second fin structure.

Abstract: Various aspects of this disclosure provide a method of manufacturing an electronic device and an electronic device manufactured thereby. As a non-limiting example, various aspects of this disclosure provide a method of manufacturing an electronic device, and an electronic device manufactured thereby, that utilizes ink to form an intermetallic bond between respective conductive interconnection structures of a semiconductor die and a substrate.

Abstract: A semiconductor device includes a semiconductor part having a first surface and a second surface opposite to the first surface, a first electrode on the first surface, a second electrode on the second surface, first to third control electrodes between the first electrode and the semiconductor part. The first to third control electrodes are biased independently from each other. The semiconductor part includes a first layer of a first-conductivity-type, a second layer of a second-conductivity-type, a third layer of the first-conductivity-type and the fourth layer of the second-conductivity-type. The second layer is provided between the first layer and the first electrode. The third layer is selectively provided between the second layer and the first electrode. The fourth layer is provided between the first layer and the second electrode. The second layer opposes the first to third control electrode with insulating films interposed.

Abstract: The disclosure is directed to spin-orbit torque (“SOT”) magnetoresistive random-access memory (“MRAM”) (“SOT-MRAM”) structures and methods. A new structure of the SOT channel has one or more magnetic insertion layers superposed or stacked with one or more heavy metal layer(s). Through proximity to a magnetic insertion layer, a surface portion of a heavy metal layer is magnetized to include a magnetization. The magnetization within the heavy metal layer enhances spin-dependent scattering, which leads to increased transverse spin imbalance.

Abstract: Multi-gate devices and methods for fabricating such are disclosed herein. An exemplary method includes forming a gate dielectric layer around first channel layers in a p-type gate region and around second channel layers in an n-type gate region. Sacrificial features are formed between the second channel layers in the n-type gate region. A p-type work function layer is formed over the gate dielectric layer in the p-type gate region and the n-type gate region. After removing the p-type work function layer from the n-type gate region, the sacrificial features are removed from between the second channel layers in the n-type gate region. An n-type work function layer is formed over the gate dielectric layer in the n-type gate region. A metal fill layer is formed over the p-type work function layer in the p-type gate region and the n-type work function layer in the n-type gate region.

Abstract: A crystalline channel layer of a semiconductor material is formed in a backend process over a crystalline dielectric seed layer. A crystalline magnesium oxide MgO is formed over an amorphous inter-layer dielectric layer. The crystalline MgO provides physical link to the formation of a crystalline semiconductor layer thereover.

Abstract: In a method of forming a two-dimensional material layer, a nucleation pattern is formed over a substrate, and a transition metal dichalcogenide (TMD) layer is formed such that the TMD layer laterally grows from the nucleation pattern. In one or more of the foregoing and following embodiments, the TMD layer is single crystalline.

Abstract: There is disclosed the integration of a Schottky diode with a MOSFET, more in detail there is a free-wheeling Schottky diode and a power MOSFET on top of a buried grid material structure. Advantages of the specific design allow the whole surface area to be used for MOSFET and Schottky diode structures, the shared drift layer is not limited by Schottky diode or MOSFET design rules and therefore, one can decrease the thickness and increase the doping concentration of the drift layer closer to a punch through design compared to the state of the art. This results in higher conductivity and lower on-resistance of the device with no influence on the voltage blocking performance. The integrated device can operate at higher frequency. The risk for bipolar degradation is avoided.