A semiconductor device includes a substrate, an isolation structure on the substrate, a fin protruding from the substrate and through the isolation structure, a gate stack engaging the fin, and a gate spacer on sidewalls of the gate stack. The gate spacer includes an inner sidewall facing the gate stack and an outer sidewall opposing the inner sidewall. The inner sidewall has a first height measured from a top surface of the fin and a bowed structure in a top portion of the inner sidewall. The bowed structure extends towards the gate stack for a first lateral distance measured from a middle point of the inner sidewall. The first lateral distance is less than about 8% of the first height.

A long channel field-effect transistor is incorporated in a semiconductor structure. A semiconductor fin forming a channel region is configured as a loop having an opening therein. A dielectric isolation region is within the opening. Source/drain regions epitaxially grown on fin end portions within the opening are electrically isolated by the isolation region. The source/drain regions, the isolation region and the channel are arranged as a closed loop. The semiconductor structure may further include a short channel, vertical transport field-effect transistor.

The present disclosure relates to a semiconductor device and a manufacturing method, and more particularly to a semiconductor device having self-aligned isolation structures. The present disclosure provides self-aligned isolation fins that can be formed by depositing dielectric material in openings formed in a spacing layer or by replacing portions of fins with dielectric material. The self-aligned isolation fins can be separated from each other by a critical dimension of the utilized photolithography process. The separation between self-aligned isolation fins or between the self-aligned isolation fins and active fins can be approximately equal to or larger than the separations of the active fins.

A semiconductor device and a method of manufacturing the same are disclosed. The semiconductor device includes: a substrate and a channel portion. The channel portion includes a first portion including a fin-shaped structure protruding with respect to the substrate and a second portion located above the first portion and spaced apart from the first portion. The second portion includes one or more nanowires or nanosheets spaced apart from each other. Source/drain portions are arranged on two opposite sides of the channel portion in a first direction and in contact with the channel portion. A gate stack extends on the substrate in a second direction intersecting with the first direction, so as to intersect with the channel portion.

Gate-all-around integrated circuit structures having devices with channel-to-substrate electrical contact are described. For example, an integrated circuit structure includes a first vertical arrangement of horizontal nanowires above a first fin. A channel region of the first vertical arrangement of horizontal nanowires is electrically coupled to the first fin by a semiconductor material layer directly between the first vertical arrangement of horizontal nanowires and the first fin. A first gate stack is over the first vertical arrangement of horizontal nanowires. A second vertical arrangement of horizontal nanowires is above a second fin. A channel region of the second vertical arrangement of horizontal nanowires is electrically isolated from the second fin. A second gate stack is over the second vertical arrangement of horizontal nanowires.

A transistor includes oxide semiconductor stacked layers between a first gate electrode layer and a second gate electrode layer through an insulating layer interposed between the first gate electrode layer and the oxide semiconductor stacked layers and an insulating layer interposed between the second gate electrode layer and the oxide semiconductor stacked layers. The thickness of a channel formation region is smaller than the other regions in the oxide semiconductor stacked layers. Further in this transistor, one of the gate electrode layers is provided as what is called a back gate for controlling the threshold voltage. Controlling the potential applied to the back gate enables control of the threshold voltage of the transistor, which makes it easy to maintain the normally-off characteristics of the transistor.

A semiconductor device includes a substrate, a first well region of the first conductivity type, and a second well region of the second conductivity type. The semiconductor device also includes a drain region, a source region, and a gate structure. The drain region of the first conductivity type is formed in the first well region and the source region of the first conductivity type is formed in the second well region. The gate structure on the substrate includes the first gate stack near the source region and the second gate stack near the drain region. The first gate stack includes the first gate dielectric layer and the first gate electrode layer. The second gate stack includes the second gate dielectric layer and the second gate electrode layer. The thickness of the first gate dielectric layer is different from the thickness of the second gate dielectric layer.

A semiconductor device and a method of manufacturing a semiconductor device are provided. The semiconductor device includes a substrate having a trench and a gate structure in the trench. The trench includes a lower gate electrode, an upper gate electrode over the lower gate electrode and a first dielectric layer partially disposed between the lower gate electrode and the upper gate electrode. The lower gate electrode and the upper gate electrode are spaced apart from the substrate by different distances, and the lower gate electrode and the upper gate electrode are configured to receive different voltages.

The present invention provides a high-side switch device having split gates. The high-side switch device includes: at least one tie-gate high-side switch device, each having a split gate independently connected to a gate; and at least one tie-source high-side switch device, each having a split gate independently connected to a source. The at least one tie-gate high-side switch device and the at least one tie-source high-side switch device are electrically connected in parallel. The quantity ratio of the at least one tie-gate high-side switch device to the at least one tie-source high-side switch device can be adjusted to modulate the Miller capacitance of the high-side switch device having split gates.

Semiconductor devices include a first semiconductor fin. A first gate stack is formed over the first semiconductor fin. Source and drain regions are formed on respective sides of the first gate stack. An interlayer dielectric is formed around the first gate stack. A gate cut plug is formed from a dielectric material at an end of the first gate stack.