The disclosure provides a plane polishing method and a processing method of the silicon wafer. The plane polishing method includes steps of: depositing a hard mask on a silicon substrate to form a silicon wafer base material; forming an opening on the hard mask by photolithography or etching; carrying out an oxidation reaction on a portion of the silicon substrate exposed by the opening, forming an oxide layer having a bottom embedded in the silicon substrate and a top protruding and exposed outside the hard mask by oxidizing the silicon substrate; and polishing the oxide layer by chemical mechanical planarization. In the present disclosure, the surface formed by the oxide layer and the hard mask flat is flat, without a recess even in the case of large structures, thereby precisely controlling a shape and a depth of the cavity in accordance with an oxidation rate on a silicon substrate.

A method to fabricate a transistor includes implanting dopants into a semiconductor to form a drift layer having majority carriers of a first type; etching a trench into the semiconductor; thermally growing an oxide liner into and on the trench and the drift layer; depositing an oxide onto the oxide liner on the trench to form a shallow trench isolation region; implanting dopants into the semiconductor to form a drain region in contact with the drift layer and having majority carriers of the first type; implanting dopants into the semiconductor to form a body region having majority carriers of a second type; forming a gate oxide over a portion of the drift layer and the body region; forming a gate over the gate oxide; and implanting dopants into the body region to form a source region having majority carriers of the first type.

An integrated circuit (IC) includes a first capacitor, a second capacitor, and functional circuitry configured together with the capacitors for realizing at least one circuit function in a semiconductor surface layer on a substrate. The capacitors include a top plate over a LOCal Oxidation of Silicon (LOCOS) oxide, wherein a thickness of the LOCOS oxide for the second capacitor is thicker than a thickness of the LOCOS oxide for the first capacitor. There is a contact for the top plate and a contact for a bottom plate for the first and second capacitors.

In accordance with an embodiment, a method for producing a buried cavity structure includes providing a mono-crystalline semiconductor substrate, producing a doped volume region in the mono-crystalline semiconductor substrate, wherein the doped volume region has an increased etching rate for a first etchant by comparison with an adjoining, undoped or more lightly doped material of the monocrystalline semiconductor substrate, forming an access opening to the doped volume region, and removing the doped semiconductor material in the doped volume region using the first etchant through the access opening to obtain the buried cavity structure.

Provided is a semiconductor device including a substrate having a first conductivity type; an isolation structure disposed in the substrate to form an active region in the substrate; a well region having the first conductivity type, extending from an inner sidewall of the isolation structure into the active region, wherein a portion of the substrate is surrounded by the well region to form a native region in the active region; a gate structure disposed over the active region; and doped regions having a second conductivity type, disposed respectively in the active region at two sides of the gate structure, wherein a portion of the native region is sandwiched between the doped regions to form a channel region below the gate structure, and a doping concentration of the channel region is substantially equal to a doping concentration of the substrate.

A semiconductor device is formed to include a fin structure, a first trench at a first lateral end of the fin, a second trench at a second lateral end of the fin, and a filler filled on a first traverse side of the fin and a second traverse side of the fin. The filler is contained between the first trench and the second trench, and oxidized in-place to cause a stress to be exerted on the first and second traverse sides of the fin, the stress causing the fin to exhibit a tensile strain in a lateral running direction of the fin.

According to an embodiment of the present invention, a semiconductor structure includes a semiconductor substrate and a plurality of fins located on the semiconductor substrate. The plurality of fins each independently includes a bottom fin portion, a top fin portion layer, and an isolated oxide layer located in between the bottom fin portion and the top fin portion layer in the y-direction parallel to the height of the plurality of fins. The isolated oxide layer includes a mixed oxide region located in between oxidized regions in an x-direction perpendicular to the height of the plurality of fins.

The disclosed technology generally relates to semiconductor fabrication and more particularly to forming vertical transistor devices. In an aspect, a method of forming a vertical transistor device includes forming, on a substrate, a fin comprising a stack including a first layer, a second layer formed above the first layer and a third layer formed above the second layer. The method additionally includes forming a gate layer serving as an etch mask above the third layer. The method further includes etching the second and third layers of the fin using the gate layer as the etch mask to form a pillar. First and third layers of the pillar define a source region and a drain region, respectively, of the vertical transistor device. A second layer of the pillar defines a channel region of the vertical transistor device. The gate layer comprises a gate electrode arranged on at least one sidewall of the second layer.

A method to fabricate a transistor includes implanting dopants into a semiconductor to form a drift layer having majority carriers of a first type; etching a trench into the semiconductor; thermally growing an oxide liner into and on the trench and the drift layer; depositing an oxide onto the oxide liner on the trench to form a shallow trench isolation region; implanting dopants into the semiconductor to form a drain region in contact with the drift layer and having majority carriers of the first type; implanting dopants into the semiconductor to form a body region having majority carriers of a second type; forming a gate oxide over a portion of the drift layer and the body region; forming a gate over the gate oxide; and implanting dopants into the body region to form a source region having majority carriers of the first type.

An integrated circuit (IC) includes a first capacitor, a second capacitor, and functional circuitry configured together with the capacitors for realizing at least one circuit function in a semiconductor surface layer on a substrate. The capacitors include a top plate over a LOCal Oxidation of Silicon (LOCOS) oxide, wherein a thickness of the LOCOS oxide for the second capacitor is thicker than a thickness of the LOCOS oxide for the first capacitor. There is a contact for the top plate and a contact for a bottom plate for the first and second capacitors.