A method of fabricating transistors with a vertical gate in trenches includes lithographing to form wide trenches; forming dielectric in the trenches and filling the trenches with flowable material; and lithography to form narrow trenches within the wide trenches thereby exposing well or substrate before epitaxially growing semiconductor strips atop substrate exposed by the narrow trenches; removing the flowable material; growing gate oxide on the semiconductor strip; forming gate conductor over the gate oxide and into gaps between the epitaxially-grown semiconductor strips and the dielectric; masking and etching the gate conductor; and implanting source and drain regions. The transistors formed have semiconductor strips extending from a source region to a drain region, the semiconductor strips within trenches, the trench walls insulated with a dielectric, a gate oxide formed on both vertical walls of the semiconductor strip; and gate material between the dielectric and gate oxide.

Various embodiments of the present disclosure provide a method for forming a recessed gate electrode that has high thickness uniformity. A gate dielectric layer is deposited lining a recess, and a multilayer film is deposited lining the recess over the gate dielectric layer. The multilayer film comprises a gate electrode layer, a first sacrificial layer over the gate dielectric layer, and a second sacrificial layer over the first sacrificial dielectric layer. A planarization is performed into the second sacrificial layer and stops on the first sacrificial layer. A first etch is performed into the first and second sacrificial layers to remove the first sacrificial layer at sides of the recess. A second etch is performed into the gate electrode layer using the first sacrificial layer as a mask to form the recessed gate electrode. A third etch is performed to remove the first sacrificial layer after the second etch.

An apparatus includes a first lateral diffusion field effect transistor (LDFET) having a first threshold voltage and that includes a first gate electrode, a first drain contact, a first source contact, and a first electrically conductive shield plate separated from the first gate electrode and the first source contact by a first interlayer dielectric. A second LDFET of the apparatus has a second threshold voltage and includes a second gate electrode, a second drain contact, and a second source contact. The second source contact is electrically connected to the first source contact of the first LDFET. A control circuit of the apparatus is electrically coupled to the first electrically conductive shield plate and is configured to apply to the first electrically conductive shield plate a first gate bias voltage of a first level to set the first threshold voltage of the first LDFET to a first desired threshold voltage.

An embodiment of a semiconductor device includes an MOS transistor having a gate that is formed to have a gate width that extends vertically into the semiconductor material in which the MOS transistor is formed. A gate length of the MOS transistor is formed to traverse substantially laterally and substantially parallel to a surface of the semiconductor material in which the MOS transistor is formed.

A transistor structure including a substrate, a gate, a first dielectric layer, a first contact and a second contact is provided. The gate is disposed on the substrate. The first dielectric layer is disposed on the substrate. The first dielectric layer covers a portion of a top surface of the gate. The first contact is electrically connected to the gate. The second contact is disposed on the first dielectric layer. The second contact is electrically connected with the first contact.

The present invention provides an image pickup device that recognizes the object that the user is attempting to capture as the subject, tracks the movement of that subject, and can continue tracking the movement of the subject even when the subject leaves the capturing area so that the subject can always be reliably brought into focus. The image pickup device includes a main camera that captures the subject; an EVF that displays the captured image captured by the main camera, a sub-camera that captures the subject using a wider capturing region than the main camera, and a processing unit that extracts the subject from the captured images captured by the main camera and the sub-camera, tracks the extracted subject, and brings the subject into focus when an image of the subject is actually captured. When the subject moves outside of a capturing region of the main camera, the processing unit tracks the subject extracted from the captured image captured by the sub-camera.

A method is provided for etching a dielectric layer covering a top and a flank of a three-dimensional structure, the method including: a first etching of the dielectric layer, including: a first fluorine-based compound and oxygen, the first etching being performed to: form a first protective layer on the top and form a second protective layer on the dielectric layer, a second etching configured to remove the second protective layer while retaining a portion of the first protective layer, the first and the second etchings being repeated until removing the dielectric layer located on the flank of the structure, and before deposition of the dielectric layer, a formation of an intermediate protective layer between the top and the dielectric layer.

A structure includes a semiconductor-on-insulator (SOI) substrate including a semiconductor substrate, a buried insulator layer over the semiconductor substrate, and an SOI layer over the buried insulator layer. At least one polycrystalline active region fill shape is in the SOI layer. A polycrystalline isolation region may be in the semiconductor substrate under the buried insulator layer. The at least one polycrystalline active region fill shape is laterally aligned over the polycrystalline isolation region, where provided. Where provided, the polycrystalline isolation region may extend to different depths in the semiconductor substrate.

A semiconductor device of the present invention includes a gate electrode buried in a gate trench of a first conductivity-type semiconductor layer, a first conductivity-type source region, a second conductivity-type channel region, and a first conductivity-type drain region formed in the semiconductor layer, a second trench selectively formed in a source portion defined in a manner containing the source region in the surface of the semiconductor layer, a trench buried portion buried in the second trench, a second conductivity-type channel contact region selectively disposed at a position higher than that of a bottom portion of the second trench in the source portion, and electrically connected with the channel region, and a surface metal layer disposed on the source portion, and electrically connected to the source region and the channel contact region.

In one aspect, a method of forming a trench in a semiconductor material includes forming a first dielectric layer on a semiconductor substrate. The first dielectric layer includes first openings. An epitaxial layer is grown on the semiconductor substrate by an epitaxial lateral overgrowth process. The first openings are filled by the epitaxial layer and the epitaxial layer is grown onto adjacent portions of the first dielectric layer so that part of the first dielectric layer is uncovered by the epitaxial layer and a gap forms between opposing sidewalls of the epitaxial layer over the part of the first dielectric layer that is uncovered by the epitaxial layer. The gap defines a first trench in the epitaxial layer that extends to the first dielectric layer.