Transistors including one or more semiconductor fins formed on a substrate. The one or more semiconductor fins are thinner in a channel region than in source and drain regions and have rounded corners. There is a gate stack on the channel region of the one or more semiconductor fins.

A semiconductor device having a silicon carbide (SiC) substrate, a SiC layer formed on a front surface of the SiC substrate, a first region selectively formed in the SiC layer at a surface thereof, a source region and a contact region formed in the first region, a gate insulating film disposed on the SiC layer and on a portion of the first region between the SiC layer and the source region, a gate electrode disposed on the gate insulating film above the portion of the first region, an interlayer insulating film covering the gate electrode, a source electrode electrically connected to the source region and the contact region, a drain electrode formed on a back surface of the SiC substrate, a first barrier film formed on, and covering, the interlayer insulating film, and a metal electrode formed on the source electrode and the first barrier film.

High voltage isolation devices for semiconductor devices and associated systems, are disclosed herein. The isolation device may support operations of a 3-dimensional NAND memory array of the semiconductor device. In some embodiments, during high voltage operations (e.g., erase operations), the isolation device may provide a high voltage to the memory array while isolating other circuitry supporting low voltage operations of the memory array from the high voltage. The isolation device may include a set of narrow active areas separating the low voltage circuitry from the high voltage and a gate over the narrow active areas. In a further embodiment, the isolation device includes interdigitated narrow active areas and a common gate over the interdigitated narrow active areas to reduce an area occupied by the isolation devices.

A semiconductor device includes a semiconductor part, a first electrode and control electrodes at the front side of the semiconductor part. The semiconductor part includes first to fourth layers, first and third layers being of a first conductivity type, second and fourth layers being of a second conductivity type. The control electrodes are provided in a plurality of trenches, respectively. The control electrodes include a first control electrode, and a second control electrode next to the first control electrode. The second layer is provided between the first layer and the first electrode. The third and fourth layers are provided between the second layer and the first electrode. The semiconductor part further includes a first region partially provided between the first and second layers. The first region is provided between the first and third layers, the first region including a material having a lower thermal conductivity than the first layer.

A semiconductor device comprises a gate cut portion disposed between a first gate region and a second gate region. The gate cut portion comprises a dielectric liner layer disposed around a vacant area. The dielectric liner layer encloses the vacant area, and the gate cut portion isolates the first gate region from the second gate region.

Provided is a highly reliable semiconductor device having both a low conduction loss and a low switching loss, and, at the same time, can enhance turn-off cut-off resistance. The semiconductor device includes a switching gate and a carrier control gate that are driven independently of each other, and is characterized by comprising, as viewed in plan, a central region cell, a peripheral region cell surrounding the circumference of the central region cell, and a terminal region surrounding the circumference of the peripheral region cell, in which the central region cell includes a switching element having the switching gate and the carrier control gate, and the peripheral region cell is disposed between the central region cell and the terminal region, the switching element of the peripheral region cell having a gate only composed of the carrier control gate.

Semiconductor devices include a strain-inducing layer capable of applying a strain to a channel region of a transistor included in a miniaturized electronic device, and a method of manufacturing the semiconductor device. The semiconductor device includes a substrate having a channel region; a pair of source/drain regions provided on the substrate and arranged on both sides of the channel region in a first direction; and a gate structure provided on the channel region and comprising a gate electrode pattern extending in a second direction that is different from the first direction, a gate dielectric layer disposed between the channel region and the gate electrode pattern, and a gate spacer covering respective lateral surfaces of the gate electrode pattern and the gate dielectric layer. At least one of the source/drain regions includes a first strain-inducing layer and a second strain-inducing layer. The first strain-inducing layer is disposed between a lateral surface of the channel region and the second strain-inducing layer and contacts at least a portion of the gate dielectric layer.

A HEMT cell includes two or more gallium nitride (GaN) high-electron-mobility transistor (HEMT) devices electrically connected in series with each other. The HEMT cell includes a HEMT cell drain, a HEMT cell source, and a HEMT cell gate. The HEMT cell drain connects with the drain of a first GaN HEMT device in the series. The HEMT cell source connects with the source of a last GaN HEMT device in the series. The HEMT cell gate connects to a first two-dimensional electron gas (2DEG) gate bias resistor that connects with the gate of the first GaN HEMT device. The HEMT cell gate connects to a second 2DEG gate bias resistor that connects with the gate of the second GaN HEMT device. The first and second 2DEG gate bias resistors are located in a 2DEG layer of the HEMT cell. A multi-throw RF switch is also disclosed.

In a method for manufacturing a semiconductor device, when a second conductive type impurity layer is formed to provide a deep layer having a second conductive type in a first concavity and to provide a channel layer having the second conductive type on a surface of a drift layer, an epitaxial growth is performed under a growth condition that a contact trench provided by a recess is formed on a surface of a part of the second conductive type impurity layer corresponding to a center position of the first concavity, and a contact region is formed by ion-implanting a second conductive type impurity on a bottom of the contact trench.

The invention concerns a method of forming a semiconductor layer having uniaxial stress including: forming, in a semiconductor structure having a stressed semiconductor layer, one or more first isolation trenches in a first direction for delimiting a first dimension of at least one transistor to be formed in said semiconductor structure; forming, in the semiconductor structure, one or more second isolation trenches in a second direction for delimiting a second dimension of the at least one transistor, the first and second isolation trenches being at least partially filled with an insulating material; and before or after the formation of the second isolation trenches, decreasing the viscosity of the insulating material in the first isolation trenches by implanting atoms of a first material into the first isolation trenches, wherein atoms of the first material are not implanted into the second isolation trenches.