Disclosed herein are IC structures, packages, and devices that include III-N transistors integrated on the same support structure as non-III-N transistors (e.g., Si-based transistors), using semiconductor regrowth. In one aspect, a non-III-N transistor may be integrated with an III-N transistor by depositing a III-N material, forming an opening in the III-N material, and epitaxially growing within the opening a semiconductor material other than the III-N material. Since the III-N material may serve as a foundation for forming III-N transistors, while the non-III-N material may serve as a foundation for forming non-III-N transistors, such an approach advantageously enables implementation of both types of transistors on a single support structure. Proposed integration may reduce costs and improve performance by enabling integrated digital logic solutions for III-N transistors and by reducing losses incurred when power is routed off chip in a multi-chip package.

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 method for making a semiconductor structure includes forming a first fin and a second fin over a substrate. The method includes forming one or more work function layers over the first and second fins. The method includes forming a nitride-based metal film over the one or more work function layers. The method includes covering the first fin with a patternable layer. The method includes removing a second portion of the nitride-based metal film from the second fin, while leaving a first portion of the nitride-based metal film over the first fin substantially intact.

A field effect transistor includes a semiconductor substrate and multiple trenches disposed at a top surface of the semiconductor substrate. The trenches extend in a first direction at the top surface of the semiconductor substrate, and are disposed to be spaced apart in a direction perpendicular to the first direction. Connection regions are disposed below body regions. The connection regions extend in a second direction intersecting the first direction in a top view of the semiconductor substrate, and are spaced apart in a direction perpendicular to the second direction. Field relaxation regions are disposed below the connection regions and the trenches. The field relaxation regions extend in a third direction intersecting the first direction and the second direction in the top view of the semiconductor substrate, and are spaced apart in a direction perpendicular to the third direction.

A semiconductor memory device including a substrate including an active pattern that includes a first source/drain region and a second source/drain region; an insulating layer on the substrate; a line structure on the insulating layer and extending in a first direction to cross the active pattern, the line structure penetrating the insulating layer on the first source/drain region and including a bit line electrically connected to the first source/drain region; and a contact spaced apart from the line structure and electrically connected to the second source/drain region, wherein the bit line includes a first portion vertically overlapped with the first source/drain region; and a second portion vertically overlapped with the insulating layer, and wherein a lowermost level of a top surface of the first portion of the bit line is at a level lower than a lowermost level of a top surface of the second portion of the bit line.

Disclosed is a method for manufacturing a contact hole, a semiconductor structure and electronic equipment. The method includes: forming a mask layer on an upper end face of a first oxide layer of the semiconductor structure, and exposing a pattern of a target contact hole on the mask layer; exposing a portion, corresponding to a target contact hole, of an upper end face of a contact layer and a portion, corresponding to the target contact hole, of an upper end face of an upper layer structure; depositing a second insulation layer on an etched surface, and depositing a second oxide layer on the second insulation layer; and removing portions, above the upper end face of the first oxide layer, of the second insulation layer and the second oxide layer, and removing a part of the contact layer, and exposing an upper end face of a zeroth layer contact.

A semiconductor device includes an N+ type substrate, an N− type layer disposed on a first surface of the N+ type substrate and having a trench opened to a surface opposite to the surface facing the N+ type substrate, a P type region disposed in the N− type layer and disposed on a side surface of the trench, a gate electrode disposed in the trench, and a source electrode and a drain electrode insulated from the gate electrode. The N− type layer includes a P type shield region covering a bottom surface and an edge of the trench.

A semiconductor device includes: a substrate (10); a semiconductor layer (20) disposed on a main surface of this substrate (10); and a first main electrode (30) and a second main electrode (40), which are disposed on the substrate (10) separately from each other with the semiconductor layer (20) sandwiched therebetween and are individually end portions of a current path of a main current flowing in an on-state. The semiconductor layer (20) includes: a first conductivity-type drift region (21) through which a main current flows; a second conductivity-type column region (22) that is disposed inside the drift region (21) and extends in parallel to a current path; and an electric field relaxation region (23) that is disposed in at least a part between the drift region (21) and the column region (22) and is either a low-concentration region in which an impurity concentration is lower than in the same conductivity-type adjacent region or a non-doped region.

An integrated circuit device includes a device isolation trench defining an active area, a gate trench extending in a first direction across the active area and the device isolation film, a gate dielectric film covering an inner wall of the gate trench, and a conductive line filling a part of the gate trench above the gate dielectric film. The active area includes a fin body portion located under the conductive line, and a thinner fin portion protruding from the fin body portion toward the conductive line and having a width less than a width of the fin body portion in the first direction.

A semiconductor device includes: a drift region of a first conductive type including a contact section and extension sections extending along the main surface of a substrate; column regions of a second conductive type which alternate with the extension sections in a perpendicular direction to the extension direction of the extension sections and each includes an end connecting to the contact section; a well region of a second conductive type which connects to the other end of each column region and tips of the extension sections; and electric field relaxing electrodes which are provided above at least some of residual pn junctions with an insulating film interposed therebetween. Herein, the residual pn junctions are pn junctions other than voltage holding pn junctions formed in interfaces between the extension sections and the column regions.