Disclosed is an LDMOS device comprising a drift region formed by a selected area of a doped layer of a first conductivity type on a semiconductor substrate, a gate structure comprising a gate dielectric layer and a gate conductive layer which are sequentially formed on a surface of the doped layer of the first conductivity type, a doped self-aligned channel region of a second conductivity type, and a doped layer formed by tilted ion implantation with a first side face of the gate structure as a self-alignment condition. A method for manufacturing an LDMOS device is further disclosed. The channel length is not affected by lithography and thus can be minimized to fulfill an ultralow specific-on-resistance, and the distribution uniformity of the channel length can be improved, so that the performance uniformity of the device is improved.

The present disclosure provides methods for forming a channel structure in a film stack for manufacturing three dimensional (3D) stacked memory cell semiconductor devices. In one embodiment, a memory cell device includes a film stack comprising alternating pairs of dielectric layers and conductive structures horizontally formed on a substrate, and a channel structure formed in the film stack, wherein the channel structure is filled with a channel layer and a protective blocking layer, wherein the channel layer has a gradient dopant concentration along a vertical stacking of the film stack.

A three-dimensional semiconductor device including a conductive layer disposed on a substrate and including a first conductivity-type impurity; an insulating base layer disposed on the conductive layer; a stack structure including a lower insulating film disposed on the insulating base, layer, and a plurality of gate electrodes and a plurality of mold insulating layers alternately stacked on the lower insulating film, wherein the insulating base layer includes a high dielectric material; a vertical structure including a vertical channel layer penetrating through the stack structure arid a vertical insulating layer disposed between the vertical channel layer and the plurality of gate electrodes, the vertical structure having an extended area extending in a width direction in the insulating base layer; and an isolation structure penetrating through the stack structure, the insulating base layer and the conductive layer, and extending in a direction parallel to an upper surface of the substrate, wherein the conductive layer has an extension portion extending along a surface of the vertical channel layer in the extended area of the vertical structure.

A semiconductor device having a channel region that is formed in a germanium layer and has a first conductive type, and a source region and a drain region that are formed in the germanium layer and have a second conductive type different from the first conductive type, wherein an oxygen concentration in the channel region is less than an oxygen concentration in a junction interface between at least one of the source region and the drain region and a region that surrounds the at least one of the source region and the drain region and has the first conductive type.

Semiconductor devices and methods for manufacturing the same are provided. In one embodiment, the method may include: forming a first shielding layer on a substrate, and forming one of source and drain regions with the first shielding layer as a mask; forming a second shielding layer on the substrate, and forming the other of the source and drain regions with the second shielding layer as a mask; removing a portion of the second shielding layer which is next to the other of the source and drain regions; forming a gate dielectric layer, and forming a gate conductor as a spacer on a sidewall of a remaining portion of the second shielding layer; and forming a stressed interlayer dielectric layer on the substrate.

A MISFET has a threshold voltage that is not undesirably increased due to channel narrowing of the MISFET, and the MISFET is reduced in size and increased in withstand voltage. An anti-inversion p-type channel stopper region provided below an element isolation trench has an end that projects toward a channel region below a gate oxide film, and terminates short of the channel region. That is, the end is offset from the end of the channel region (the end of the element isolation trench). This suppresses diffusion in a lateral direction (channel region direction) of an impurity in the p-type channel stopper region, and thus suppresses a decrease in carrier concentration at the end of the channel region. As a result, a local increase in threshold voltage is suppressed.

The application provides a method for manufacturing a semiconductor device. The method includes the following operations. A semiconductor substrate is provided, a plurality of separate trenches being formed in the semiconductor substrate. Plasma injection is performed to form a barrier layer between adjacent trenches A respective gate structure is formed in each of the plurality of trenches. A plurality of channel regions are formed in the semiconductor substrate, each of the plurality of trenches corresponding to a respective one of the plurality of channel regions. A source/drain region is formed between each of the plurality of trenches and the barrier layer, the source/drain region being electrically connected to the respective one of the plurality of channel regions, and a conductive type of the barrier layer is opposite to a conductive type of the source/drain region.

A FinFET whose fin has an upper portion doped with a first conductivity type and a lower portion doped with a second conductivity type, and the junction between the upper portion and the lower portion acts as a diode. The FinFET further includes: at least one layer of high-k dielectric material (for example Si.sub.3N.sub.4) adjacent at least one side of the fin for redistributing a potential drop more evenly over the diode. Examples of the k value for the high-k dielectric material are k≧5, k≧7.5, and k≧20.

A method of forming a semiconductor device includes depositing a p-type semiconductor layer over a portion of a semiconductor substrate, depositing a semiconductor layer over the p-type semiconductor layer, wherein the semiconductor layer is free from p-type impurities, forming a gate stack directly over a first portion of the semiconductor layer, and etching a second portion of the semiconductor layer to form a trench extending into the semiconductor layer. At least a surface of the p-type semiconductor layer is exposed to the trench. A source/drain region is formed in the trench. The source/drain region is of n-type.

A semiconductor element includes a high-resistivity substrate that includes a β-Ga.sub.2O.sub.3-based single crystal including an acceptor impurity, a buffer layer on the high-resistivity substrate, the buffer layer including a β-Ga.sub.2O.sub.3-based single crystal, and a channel layer on the buffer layer, the channel layer including a β-Ga.sub.2O.sub.3-based single crystal including a donor impurity. A crystalline laminate structure includes a high-resistivity substrate that includes a β-Ga.sub.2O.sub.3-based single crystal including an acceptor impurity, a buffer layer on the high-resistivity substrate, the buffer layer including a β-Ga.sub.2O.sub.3-based single crystal, and a donor impurity-containing layer on the buffer layer, the donor impurity-containing layer including a β-Ga.sub.2O.sub.3-based single crystal including a donor impurity.