Disclosed is a method for manufacturing a semiconductor super-junction device. The method includes: a gate is firstly formed in a gate region of a first trench, then an n-type epitaxial layer is etched with a hard mask layer and an insulating side wall covering a side wall of the gate as masks, and a second trench is formed in the n-type epitaxial layer, and then a p-type column is formed in the first trench and the second trench.

Disclosed is a method for manufacturing a semiconductor super-junction device. The method includes: a p-type column is formed through an epitaxial process, and then a gate is formed in a self-alignment manner.

A power device includes: a semiconductor layer, a well region, a body region, a gate, a source, a drain, a field oxide region, and a self-aligned drift region. The field oxide region is formed on an upper surface of the semiconductor layer, wherein the field oxide region is located between the gate and the drain. The field oxide region is formed by steps including a chemical mechanical polish (CMP) process step. The self-aligned drift region is formed in the semiconductor layer, wherein the self-aligned drift region is entirely located vertically below and in contact with the field oxide region.

A display apparatus and a method of manufacturing the same are provided. According to an embodiment, a display apparatus includes: a substrate; a thin-film transistor located on the substrate; and a buffer layer, a conductive layer, and an insulating layer sequentially located from the substrate between the substrate and the thin-film transistor, and a thickness of the insulating layer is less than a thickness of the buffer layer.

In a method of manufacturing a semiconductor device, a fin structure, in which first semiconductor layers and second semiconductor layers are alternately stacked, is formed over a bottom fin structure. A sacrificial gate structure having sidewall spacers is formed over the fin structure. A source/drain region of the fin structure, which is not covered by the sacrificial gate structure, is removed. The second semiconductor layers are laterally recessed. Dielectric inner spacers are formed on lateral ends of the recessed second semiconductor layers. The first semiconductor layers are laterally recessed. A source/drain epitaxial layer is formed to contact lateral ends of the recessed first semiconductor layer. The second semiconductor layers are removed thereby releasing the first semiconductor layers in a channel region. A gate structure is formed around the first semiconductor layers.

The present invention provides semiconductor devices with super junction drift regions that are capable of blocking voltage. A super junction drift region is an epitaxial semiconductor layer located between a top electrode and a bottom electrode of the semiconductor device. The super junction drift region includes a plurality of pillars having P type conductivity, formed in the super junction drift region, which are surrounded by an N type material of the super junction drift region.

A pixel includes a workpiece having a protrusion and a bulk, wherein the protrusion extends from an upper surface of the bulk. The pixel further includes a protrusion doping region in the protrusion. The pixel further includes a photosensitive device comprising a plurality of first regions, wherein each of the plurality of first regions is in the bulk and the protrusion.

A method includes depositing a multi-layer stack over a semiconductor substrate, the multi-layer stack including a plurality of sacrificial layers that alternate with a plurality of channel layers; forming a first recess in the multi-layer stack; forming first spacers on sidewalls of the sacrificial layers in the first recess; depositing a first semiconductor material in the first recess, where the first semiconductor material is undoped, where the first semiconductor material is in physical contact with a sidewall and a bottom surface of at least one of the first spacers; implanting dopants in the first semiconductor material, where after implanting dopants the first semiconductor material has a gradient-doped profile; and forming an epitaxial source/drain region in the first recess over the first semiconductor material, where a material of the epitaxial source/drain region is different from the first semiconductor material.

A method can include ion implanting with the gate mask to form first halo regions and ion implanting with the gate mask and first spacers as a mask to form second halo regions. The gate mask and first spacers can be removed, and an epitaxial layer formed. A dummy gate mask can be formed. Ion implanting with the dummy gate mask can from source-drain extensions. Second spacers can be formed on sides of the dummy gate mask. Ion implanting with the dummy gate mask and second spacers as a mask can form source and drain regions. A surface dielectric layer can be formed and planarized to expose a top of the dummy gate. The dummy gate can be removed to form gate openings between the second spacers. A hi-K dielectric layer and at least two gate metal layers within the gate opening. Related devices are also disclosed.

A semiconductor device includes: a semiconductor substrate including a front surface, a back surface that is opposite to the front surface, and a drift layer of a first conductive type disposed between the front surface and the back surface; a first diffusion layer of a second conductive type provided between the drift layer and the front surface; a second diffusion layer provided between the drift layer and the back surface; a first buffer layer of the first conductive type provided between the drift layer and the second diffusion layer, having a concentration higher than that of the drift layer, and into which a proton is injected; and a second buffer layer of the first conductive type provided between the first buffer layer and the second diffusion layer and having a concentration higher than that of the drift layer, wherein a peak concentration of the second buffer layer is higher than a peak concentration of the first buffer layer, an impurity concentration of the first buffer layer gradually decreases toward the back surface, a length from a peak position of the first buffer layer to a boundary between the drift layer and the first buffer layer is represented by Xa, a length from the peak position to a boundary between the first buffer layer and the second buffer layer is represented by Xb, and Xb>5 Xa.