There are provided a semiconductor device, a method of manufacturing the same, and an electronic device including the device. According to an embodiment, the semiconductor device may include a substrate, and a first device and a second device formed on the substrate. Each of the first device and the second device includes a first source/drain layer, a channel layer and a second source/drain layer stacked on the substrate in sequence, and also a gate stack surrounding a periphery of the channel layer. The channel layer of the first device and the channel layer of the second device are substantially co-planar.

A semiconductor device is provided. The semiconductor device includes a pair of channel structures each configured to have a current direction along a first direction substantially parallel to a working surface of a substrate. The semiconductor device also includes source/drain (S/D) structures on opposing sides of the pair of channel structures along the first direction. The semiconductor device further includes a gate structure between the pair of channel structures. The pair of channel structures includes two-dimensional (2D) semiconductor material oriented substantially perpendicular to the working surface of the substrate.

A method of manufacturing an integrated circuit includes: growing an epitaxial layer on a process surface of a base substrate; forming, by processes applied to an exposed first surface of the epitaxial layer, first transistor cells in the epitaxial layer, each first transistor cell including a first gate electrode; and forming, by processes applied to a surface opposite to the first surface, second transistor cells, each second transistor cell including a second gate electrode.

A portion of an AlN spacer layer of a high electron mobility transistor (GaN HEMI) having a nitride semiconductor used therein is removed only in a region directly below a gate electrode and in a vicinity of the region, and a length of a portion where the AlN spacer layer is not present is sufficiently smaller than a distance between a source electrode and a drain electrode.

In one implementation, a power semiconductor package includes a power transistor having a first power electrode and a gate electrode on its bottom surface, and a second power electrode on its top surface. The first power electrode is configured for attachment to a first partially etched conductive carrier segment and the gate electrode is configured for attachment to a second partially etched conductive carrier segment. The power semiconductor package also includes a power electrode heat spreader situated over the second power electrode and configured for attachment to a power electrode conductive carrier segment.

A semiconductor device includes a semiconductor body including first and second lateral surfaces. A first device region includes a drift region of a first conductivity type, and a drift current control region of a second conductivity type being spaced apart from the second lateral surface by the drift region. A second device region includes a barrier layer, and a buffer layer having a different band gap than the barrier layer so that a two-dimensional charge carrier gas channel arises along an interface between the buffer layer and the barrier layer. An electrically conductive substrate contact forms a low ohmic connection between the two-dimensional charge carrier gas channel and the drift region. A gate structure is configured to control a conduction state of the two-dimensional charge carrier gas. The drift current control region is configured to block a vertical current in the drift region via a space-charge region.

A semiconductor device includes a semiconductor body including first and second lateral surfaces. A first device region includes a drift region of a first conductivity type, and a drift current control region of a second conductivity type being spaced apart from the second lateral surface by the drift region. A second device region includes a barrier layer, and a buffer layer having a different band gap than the barrier layer so that a two-dimensional charge carrier gas channel arises along an interface between the buffer layer and the barrier layer. An electrically conductive substrate contact forms a low ohmic connection between the two-dimensional charge carrier gas channel and the drift region. A gate structure is configured to control a conduction state of the two-dimensional charge carrier gas. The drift current control region is configured to block a vertical current in the drift region via a space-charge region.

A semiconductor structure is provided comprising a vertical channel structure extending from a substrate and formed as a channel between a source region and a drain region. The semiconductor structure further comprises a metal gate that surrounds a portion of the vertical channel structure. The metal gate has a gate length. The metal gate has a first gate section with a first workfunction and a first thickness. The metal gate also has a second gate section with a second workfunction and a second thickness. The first thickness level is different from the second thickness level and the sum of the first thickness level and the second thickness level is equal to the gate length. The ratio of the first thickness level to the second thickness level for the gate length was chosen to achieve a threshold voltage level for the semiconductor device.

A HEMT device comprising a III-Nitride material substrate, the surface of which follows a plane that is not parallel to the C-plane of the III-Nitride material; an epitaxial layer of III-Nitride material grown on said substrate; a recess etched in said epitaxial layer, having at least one plane wall parallel to a polar plane of the III-Nitride material; a carrier supply layer formed on a portion of the plane wall of the recess, such that a 2DEG region is formed along the portion of the plane wall of the recess; a doped source region formed at the surface of said epitaxial layer such that the doped source region is separated from said 2DEG region by a channel region of the epitaxial layer; a gate insulating layer formed on the channel region of the epitaxial layer; and a gate contact layer formed on the gate insulating layer.

The present invention provides a field effect transistor device and a method for improving the short-channel effect and the output characteristics using the same. The field effect transistor device comprises an active layer comprising a source region, a drain region, and a channel region located between the source region and the drain region; when the device is turned on, an effective channel and an equivalent source and/or equivalent drain away from the effective channel are formed in the channel region, and the field effect transistor device connects the source region with the drain region through the effective channel, and the equivalent source and/or equivalent drain to form an operating current.