Provided is a semiconductor device in which a leakage current is reduced, the semiconductor device which is particularly useful for power devices. A semiconductor device including at least: an n+-type semiconductor layer, which contains a crystalline oxide semiconductor as a major component; an n−-type semiconductor layer that is placed on the n+-type semiconductor layer, the n−-type semiconductor layer containing a crystalline oxide semiconductor as a major component; a high-resistance layer with at least a part thereof being embedded in the n−-type semiconductor layer, the high-resistance layer having a bottom surface located at a distance of less than 1.5 μm from an upper surface of the n+-type semiconductor layer; and a Schottky electrode that forms a Schottky junction with the n−-type semiconductor layer, the Schottky electrode having an edge located on the high-resistance layer.

Embodiments herein describe techniques, systems, and method for a semiconductor device. Embodiments herein may present a semiconductor device having a channel area including a channel III-V material, and a source area including a first portion and a second portion of the source area. The first portion of the source area includes a first III-V material, and the second portion of the source area includes a second III-V material. The channel III-V material, the first III-V material and the second III-V material may have a same lattice constant. Moreover, the first III-V material has a first bandgap, and the second III-V material has a second bandgap, the channel III-V material has a channel III-V material bandgap, where the channel material bandgap, the second bandgap, and the first bandgap form a monotonic sequence of bandgaps. Other embodiments may be described and/or claimed.

A nitride-based semiconductor device includes a first and second nitride-based semiconductor layers, a doped III-V semiconductor layer, a gate electrode, a first and second source/drain (S/D) electrodes. The doped III-V semiconductor layer is disposed over the second nitride-based semiconductor layer and has first and second current-leakage barrier portions which extends downward from atop surface of the doped III-V semiconductor layer. The gate electrode is disposed above the doped III-V semiconductor layer, in which the gate electrode has a pair of opposite edges between the first and second current-leakage barrier portions. One of the edges of the gate electrode coincides with the first current-leakage barrier portion. The first current-leakage barrier portion is located between the first S/D electrode and the gate electrode. The second current-leakage barrier portion is located between the second S/D electrode and the gate electrode.

A high electron mobility transistor (HEMT) includes an active region, in which a channel is formed, and a field region surrounding the active region. The HEMT may include a channel layer; a barrier layer on the channel layer and configured to induce a two-dimensional electron gas (2DEG) in the channel layer; a source and a drain on the barrier layer in the active region; and a gate on the barrier layer. The gate may protrude from the active region to the field region on the barrier layer. The gate may include a first gate and a second gate. The first gate may be in the active region and the second gate may be in the boundary region between the active region and the field region. A work function of the second gate may be different from a work function of the first gate.

Structures including III-V compound semiconductor-based devices and silicon-based devices integrated on a semiconductor substrate and methods of forming such structures. The structure includes a substrate having a device layer, a handle substrate, and a buried insulator layer between the handle substrate and the device layer. The structure includes a first semiconductor layer on the device layer in a first device region, and a second semiconductor layer on the device layer in a second device region. The first semiconductor layer contains a III-V compound semiconductor material, and the second semiconductor layer contains silicon. A first device structure includes a gate structure on the first semiconductor layer, and a second device structure includes a doped region in the second semiconductor layer. The doped region and the second semiconductor layer define a p-n junction.

A junction barrier Schottky diode device and a method for fabricating the same is disclosed. In the junction barrier Schottky device includes an N-type semiconductor layer, a plurality of first P-type doped areas, a plurality of second P-type doped areas, and a conductive metal layer. The first P-type doped areas and the second P-type doped are formed in the N-type semiconductor layer. The second P-type doped areas are self-alignedly formed above the first P-type doped areas. The spacing between every neighboring two of the second P-type doped areas is larger than the spacing between every neighboring two of the first P-type doped areas. The conductive metal layer, formed on the N-type semiconductor layer, covers the first P-type doped areas and the second P-type doped areas.

A method of forming a bipolar transistor with a vertical collector contact requires providing a transistor comprising a plurality of epitaxial semiconductor layers on a first substrate, and providing a host substrate. A metal collector contact is patterned on the top surface of the host substrate, and the plurality of epitaxial semiconductor layers is transferred from the first substrate onto the metal collector contact on the host substrate. The first substrate is suitably the growth substrate for the plurality of epitaxial semiconductor layers. The host substrate preferably has a higher thermal conductivity than does the first substrate, which improves the heat dissipation characteristics of the transistor and allows it to operate at higher power densities. A plurality of transistors may be transferred onto a common host substrate to form a multi-finger transistor.

A semiconductor device includes a substrate, a semiconductor layer disposed on the substrate, an insulating layer disposed on the semiconductor layer and having a first opening formed therein, a gate electrode disposed on the insulating layer and in contact with the semiconductor layer via the first opening, and a source electrode and a drain electrode in ohmic contact with the semiconductor layer. The gate electrode includes a crystallinity control film disposed on the insulating layer and having a second opening formed such that an inner wall thereof extends to an inner wall of the first opening toward the substrate in plan view in a direction perpendicular to a top surface of the substrate, and a first metal film disposed on the crystallinity control film and in Schottky contact with the semiconductor layer via the inner walls, extending to each other, of the second opening and the first opening.

A semiconductor component, in particular for a varactor, having at least one first semiconductor layer and a second semiconductor layer. At least two identical surface electrodes are arranged directly or indirectly on the second semiconductor layer facing away from the first semiconductor layer in order to form two anti-serially connected diodes. The surface electrodes are arranged in an interacting manner such that a load carrier zone which forms the common counter electrode for the surface electrodes is arranged in the first semiconductor layer at least in the operating state, and at least one control contact for controlling the potential of the load carrier zone is provided in a region of the load carrier zone on the second semiconductor layer face facing away from the first semiconductor layer. The load carrier zone produces a continuous electric connection from the counter electrode to the at least one control contact at least in the operating state, and the load carrier zone protrudes beyond the surface electrodes in a projection onto the rear face of the semiconductor component.

A field effect transistor comprising: a first semiconductor structure, the first semiconductor structure having a channel layer; a second semiconductor structure, the second semiconductor structure is arranged on the first semiconductor structure, and the second semiconductor structure is stacked in sequence from bottom to top with a Schottky layer, a first etch stop layer, a wide recess layer, an ohmic contact layer, and a narrow recess, a wide recess is opened in the ohmic contact layer, so that the upper surface of the wide recess layer forms a wide recess area and the upper surface of the Schottky layer forms a narrow recess area; at least one delta-doped layer, a gate metal contact, the gate metal contact is formed inside the wide recess a source metal contact; and a drain metal contact, and the drain metal contact is located on the other side of the gate metal contact.