A method for making a semiconductor device may include forming a hyper-abrupt junction region above a substrate and including a first semiconductor layer having a first conductivity type, a first superlattice layer on the first semiconductor layer, a second semiconductor layer on the first superlattice layer and having a second conductivity type different than the first conductivity type, and a second superlattice layer on the second semiconductor layer. The method may further include forming a gate dielectric layer on the second superlattice layer of the hyper-abrupt junction region, forming a gate electrode on the gate dielectric layer, and forming spaced apart source and drain regions adjacent the hyper-abrupt junction region.

A semiconductor device may include a substrate and a hyper-abrupt junction region carried by the substrate. The hyper-abrupt region may include a first semiconductor layer having a first conductivity type, a first superlattice layer on the first semiconductor layer, a second semiconductor layer on the first superlattice layer and having a second conductivity type different than the first conductivity type, and a second superlattice layer on the second semiconductor layer. The semiconductor device may further include a gate dielectric layer on the second superlattice layer of the hyper-abrupt junction region, a gate electrode on the gate dielectric layer, and spaced apart source and drain regions adjacent the hyper-abrupt junction region.

Current conducting devices and methods for their formation are disclosed. Described are vertical current devices that include a substrate, an n-type material layer, a plurality of p-type gates, and a source. The n-type material layer disposed on the substrate and includes a current channel. A plurality of p-type gates are disposed on opposite sides of the current channel. A source is disposed on a distal side of the current channel with respect to the substrate. The n-type material layer comprises beta-gallium oxide.

An IC with a split-gate transistor includes a substrate doped the second conductivity type having a semiconductor surface layer doped the first conductivity type. The transistor includes a first doped region formed as an annulus, a second doped region including under the first doped region, and a third doped region under the second doped region, all coupled together and doped the second conductivity type. A fourth doped region doped the first conductivity type is above the third doped region. A fifth doped region doped the first conductivity type is outside the annulus. Sixth doped regions doped the first conductivity type include a first sixth doped region surrounded by the annulus in the semiconductor surface layer and a second sixth doped region in the fifth doped region. Field oxide includes a field oxide portion between the fifth and the first doped region. A field plate is on the field oxide portion.

A parasitic capacitance and a leak current in a nitride semiconductor device are reduced. For example, a 100 nm-thick buffer layer made of AlN, a 2 m-thick undoped GaN layer, and 20 nm-thick undoped AlGaN having an Al composition ratio of 20% are epitaxially grown in this order on, for example, a substrate made of silicon, and a source electrode and a drain electrode are formed so as to be in ohmic contact with the undoped AlGaN layer. Further, in the undoped GaN layer and the undoped AlGaN layer immediately below a gate wire, a high resistance region, the resistance of which is increased by, for example, ion implantation with Ar or the like, is formed, and a boundary between the high resistance region and an element region is positioned immediately below the gate wire.

A semiconductor device may include a substrate and a hyper-abrupt junction region carried by the substrate. The hyper-abrupt junction region may include a first semiconductor layer having a first conductivity type, a first superlattice layer on the first semiconductor layer, a second semiconductor layer on the first superlattice layer and having a second conductivity type different than the first conductivity type, and a second superlattice layer on the second semiconductor layer. The semiconductor device may further include a first contact coupled to the hyper-abrupt junction regions and a second contact coupled to the substrate to define a varactor. The first and second superlattices may each include stacked groups of layers, with each group of layers including stacked base semiconductor monolayers defining a base semiconductor portion, and at least one non-semiconductor monolayer constrained within a crystal lattice of adjacent base semiconductor portions.

Described examples include an integrated circuit includes a protected node and a first transistor having a source coupled to the protected node, a gate and a drain coupled to a ground, wherein the first transistor is a MOSFET transistor. The integrated circuit also includes a second transistor having a first current handling terminal coupled to the protected node, a second current handling terminal coupled to the ground and a control terminal coupled to a reference potential, where the second transistor is configured to be off when a first voltage on the control terminal of the second transistor is less than a second voltage on the first current handling terminal of the second transistor.

A method is presented for forming a semiconductor device. The method may include forming a first gate structure on a first portion of a semiconductor material located on a surface of an insulating substrate, the first gate structure including a first sacrificial layer and a second sacrificial layer and forming a second gate structure on a second portion of the semiconductor material located on the surface of the insulating substrate, the second gate structure including a third sacrificial layer. The method further includes etching the first and second dielectric sacrificial layers to create a first contact region within the first gate structure and etching the third dielectric sacrificial layer to create a second contact region within the second gate structure. The method further includes forming silicide in at least the first and second contact regions of the first and second gate structures, respectively.

A chip includes a semiconductor body coupled to a first and a second load terminal. The semiconductor body includes an active region including a plurality of breakthrough cells, each of the breakthrough cells includes: an insulation structure; a drift region; an anode region, the anode region being electrically connected to the first load terminal and disposed in contact with the first load terminal; a first barrier region arranged in contact with each of the anode region and the insulation structure, where the first barrier region of the plurality of breakthrough cells forms a contiguous semiconductor layer; a second barrier region separating each of the anode region and at least a part of the first barrier region from the drift region; and a doped contact region arranged in contact with the second load terminal, where the drift region is positioned between the second barrier region and the doped contact region.

Described is a semiconductor device including a first N-type well region disposed in a substrate and a second N-type well region in contact with the first N-type well region, a source region disposed in the first N-type well region, a drain region disposed in the second N-type well region, and a first gate electrode and a second gate electrode disposed spaced apart from the drain region. A maximum vertical length of the source region in a direction vertical to the first or second gate electrode is greater than a maximum vertical length of the drain region in the direction in a plan view.