An IGBT device includes a drift region of a first doping type; a plurality of pillar regions of the second doping type, disposed at intervals in the lateral direction within the drift region; and a transition layer of the first doping type, connected under the pillar region. The thickness of the transition layer is larger than 2 microns and less than or equal to 11 microns, and the doping concentration of the transition layer ranges from larger than or equal to 2.410.sup.14/cm.sup.3 to less than or equal to 2.410.sup.16/cm.sup.3, in order to solve the technical problem of a large turn-off energy loss due to the tail current of the conventional SJ-IGBT device in the turn-off stage.

A power semiconductor device includes a substrate of a first conductivity type, a drift layer of a first conductivity type on the substrate, a well region of a second conductivity type on the drift layer, a source region of the first conductivity type on the well region, a gate electrode disposed in a gate trench penetrating through the source region and the well region, a first gate insulating layer, a second gate insulating layer, and a third gate insulating layer sequentially disposed between the well region and the gate electrode, a dielectric layer on the gate electrode, and a drain electrode on a lower surface of the substrate.

In certain examples, methods and semiconductor structures are directed to a semiconductor device having a circuit that includes an active region (e.g., a channel region of a transistor) and having a poly crystalline-diamond-based thermal field plate (TFP). The TFP, or a first portion thereof, is oriented over or under the active region. Further, the first portion is located in proximity to the active region for passing heat away from the active region, and includes a layer of poly crystalline-diamond grains with an average grain width dimension and an average thickness dimension, wherein the average grain width dimension and the average thickness dimension characterize the poly crystalline-diamond grains as being more isotropic than columnar. With the first portion, or the entire TFP, being in close proximity of the channel region, during operation of the circuit, the TFP passes heat away from the channel region to maintain a relatively low-temperature circuit.

Lateral gallium oxide transistor includes a gallium oxide substrate, an n-type gallium oxide epitaxial layer epitaxially grown on the gallium oxide substrate, an insulating layer defining a gate region, a source region, and a drain region on the n-type gallium oxide epitaxial layer, a diffusion barrier layer deposited on the n-type gallium oxide epitaxial layer exposed in the gate region, a p-type nickel oxide layer deposited on the diffusion barrier layer, a dielectric layer deposited on the p-type nickel oxide layer, a gate electrode layer deposited on the dielectric layer, and a source electrode and a drain electrode formed on the n-type gallium oxide epitaxial layer exposed in the source region and the drain region.

A 3D semiconductor device, the device including: a first level including a first single crystal layer and including first transistors which each includes a single crystal channel; a first metal layer; a second metal layer overlaying the first metal layer; a second level including second transistors, first memory cells including at least one second transistor, and overlaying the second metal layer; a third level including third transistors and overlaying the second level; a fourth level including fourth transistors, second memory cells including at least one fourth transistor, and overlaying the third level, where at least one of the second transistors includes a metal gate, where the first level includes memory control circuits which control writing to the second memory cells, and at least one Phase-Lock-Loop (PLL) circuit or at least one Digital-Lock-Loop (DLL) circuit.

A semiconductor device includes a drain, a substrate, an epitaxial layer, and a semiconductor layer. The semiconductor layer includes a source region located on a side the semiconductor layer away from the epitaxial layer. A trench extending to the epitaxial layer is disposed on a side of the source region is away from the epitaxial layer. A gate, an electrode plate, a first shield gate, and a second shield gate are disposed in the trench. The electrode plate is located between the first shield gate and the second shield gate. The trench is further filled with an oxidized layer structure. The first shield gate and the second shield gate are separately spaced from the electrode plate to form electrode plate capacitance. One of the source region, the drain, and the gate is electrically connected to the electrode plate a first electrode, and a second one of the source region, the drain, and the gate is electrically connected to the shield gate structure.

The present disclosure provides a manufacturing method and measurement method of a semiconductor structure, and a semiconductor structure, relating to the technical field of semiconductors. The manufacturing method of a semiconductor structure includes: providing a base including multiple gate trenches; and forming a gate structure in each of the gate trenches, wherein each gate structure includes a barrier layer and a conductive layer, the barrier layer and the conductive layer are sequentially stacked, the barrier layer is in contact with a bottom wall of each of the gate trenches, and a material of the conductive layers includes polysilicon.

A method includes growing an epitaxial layer over a substrate, forming a plurality of gates in the epitaxial layer, forming a breakdown voltage enhancement and leakage prevention structure in the epitaxial layer comprising a body ring structure, forming a source and a body region in the epitaxial layer, forming an interlayer dielectric layer over the epitaxial layer, forming a gate-source Electrostatic Discharge (ESD) diode structure in the interlayer dielectric layer, forming a source contact connected to the source, and a first terminal of the gate-source ESD diode structure, forming a gate contact connected to the plurality of gates and a second terminal of the gate-source ESD diode structure, and forming a drain contact underneath the substrate.

The present disclosure provides a method of manufacturing a semiconductor structure, and a semiconductor structure. The method of manufacturing a semiconductor structure includes: providing a base, where a channel is formed in the base; forming a gate conductive layer, where the gate conductive layer covers a part of the channel; and forming a semiconductor doped layer, where the semiconductor doped layer fills the channel and covers the gate conductive layer, and a doping concentration of the semiconductor doped layer at a side close to a top surface of the gate conductive layer is different from a doping concentration of the semiconductor doped layer at a side away from the top surface of the gate conductive layer.

A method of forming a gate structure on a substrate with increased charge mobility. In some embodiments, the method may include depositing an amorphous carbon layer on a silicon carbide layer on the substrate to form a capping layer on the silicon carbide layer, annealing the silicon carbide layer at a temperature of greater than approximately 1800 degrees Celsius, forming a hard mask on the silicon carbide layer by patterning the amorphous carbon layer, etching a trench structure of the gate structure into the silicon carbide layer using the hard mask, removing the hard mask to expose the silicon carbide layer, depositing a silicon dioxide layer on the silicon carbide layer using an ALD process, performing at least one interface treatment on the silicon dioxide layer, depositing a gate oxide layer of the gate structure on the silicon dioxide layer, and depositing a gate material on the gate oxide layer.