A semiconductor device includes a semiconductor layer, a source region and a drain region that are formed in the semiconductor layer and at an interval in a first direction, a gate insulating film that is formed such as to cover a channel region between the source region and the drain region, and a gate electrode that is formed on the gate insulating film and opposes the channel region across the gate insulating film. The gate insulating film has a major portion on which the gate electrode is formed and extension portions projecting outward from each of both sides of the major portion in a second direction orthogonal to the first direction and leak current suppressing electrodes are formed on the extension portions.

A method of forming a high electron mobility transistor (HEMT) includes: providing a semiconductor structure comprising a channel layer and a barrier layer sequentially stacked on a substrate; forming a first insulating layer on the barrier layer; and forming a gate contact, a source contact, and a drain contact on the barrier layer. An interface between the first insulating layer and the barrier layer comprises a modified interface region on a drain access region and/or a source access region of the semiconductor structure such that a sheet resistance of the drain access region and/or the source access region is between 300 and 400 Ω/sq.

An embodiment of a semiconductor device includes a semiconductor substrate, a first current-carrying electrode, and a second current-carrying electrode formed over the semiconductor, a control electrode formed over the semiconductor substrate between the first current carrying electrode and the second current carrying electrode, and a first dielectric layer disposed over the control electrode, and a second dielectric layer disposed over the first dielectric layer. A first opening is formed in the second dielectric layer, adjacent the control electrode and the second current-carrying electrode, having a first edge laterally adjacent to and nearer the second current-carrying electrode, and a second edge laterally adjacent to and nearer to the control electrode, and a conductive element formed over the first dielectric layer and within the first opening, wherein the portion of the conductive element formed within the first opening forms a first metal-insulator-semiconductor region within the first opening.

A GaN-based high electron mobility transistor (HEMT) device includes a semiconductor structure comprising a channel layer and a barrier layer sequentially stacked on a substrate, a drain contact and a source contact on the barrier layer, and a gate contact on the barrier layer between the drain contact and the source contact. A sheet resistance of a drain access region and/or a source access region of the semiconductor structure is between 300 and 400 Ω/sq.

A transistor device according to some embodiments includes a channel layer, a barrier layer on the channel layer, and source and drain contacts on the barrier layer, and a gate contact on the barrier layer between the source and drain contacts. The channel layer includes a sub-layer having an increased doping concentration level relative to a remaining portion of the channel layer. The presence of the sub-layer may reduce drain lag without substantially increasing gate lag.

A solid-state imaging device includes an N-type semiconductor layer, an element layer including a photoelectric conversion element and an active element, an interconnect layer providing an interconnect for the active element, and an element isolation trench penetrating the semiconductor layer. The element layer includes a P-type region and an N-type region. A first hole storage layer is formed on a surface of the semiconductor layer on a side opposite to the element layer. A second hole storage layer is formed in contact portions of the semiconductor layer and the element layer with the element isolation trench. The P-type region of the element layer and the first hole storage layer are connected to each other by the second hole storage layer.

Conformal hermetic dielectric films suitable as dielectric diffusion barriers over 3D topography. In embodiments, the dielectric diffusion barrier includes a dielectric layer, such as a metal oxide, which can be deposited by atomic layer deposition (ALD) techniques with a conformality and density greater than can be achieved in a conventional silicon dioxide-based film deposited by a PECVD process for a thinner contiguous hermetic diffusion barrier. In further embodiments, the diffusion barrier is a multi-layered film including a high-k dielectric layer and a low-k or intermediate-k dielectric layer (e.g., a bi-layer) to reduce the dielectric constant of the diffusion barrier. In other embodiments a silicate of a high-k dielectric layer (e.g., a metal silicate) is formed to lower the k-value of the diffusion barrier by adjusting the silicon content of the silicate while maintaining high film conformality and density.

An integrated circuit (IC) package comprising a-substrate having a first side and an opposing a second side, and a bridge die within the substrate. The bridge die comprises a plurality of vias extending from a first side to a second side of the-bridge die. The-bridge die comprises a first plurality of pads on the first side of the bridge die and a second plurality of pads on the second side. The plurality of vias interconnect ones of the first plurality of pads to ones of the second plurality of pads. The bridge die comprises an adhesive film over a layer of silicon oxide on the second side of the bridge die.

The present technology relates to a solid-state imaging device capable of suppressing deterioration in dark characteristics, and an electronic apparatus. The device includes a photoelectric conversion section; a trench between the photoelectric conversion sections in adjacent pixels; and a PN junction region on a sidewall of the trench and including a P-type region and an N-type region, the P-type region having a protruding region. The device can include an inorganic photoelectric conversion section having a pn junction and an organic photoelectric conversion section having an organic photoelectric conversion film that are stacked in a depth direction within a same pixel; and a PN junction region on a sidewall of the inorganic photoelectric conversion section. The PN junction region can further include a first P-type region and an N-type region; and a second P-type region. The present technology can be applied to, for example, a back-illuminated CMOS image sensor.

An apparatus configured to reduce lag includes a substrate; a group III-Nitride back barrier layer on the substrate; a group III-Nitride channel layer on the group III-Nitride back barrier layer; a group III-Nitride barrier layer on the group III-Nitride channel layer, the group III-Nitride barrier layer include a higher bandgap than a bandgap of the group III-Nitride channel layer; a source electrically coupled to the group III-Nitride barrier layer; a gate on the group III-Nitride barrier layer; a drain electrically coupled to the group III-Nitride barrier layer; and a p-region being arranged at or below the group III-Nitride barrier layer. Additionally, at least a portion of the p-region is arranged vertically below at least one of the following: the source, the gate, an area between the gate and the drain.