A semiconductor device which includes a transistor in an active area of a substrate; an isolation structure in the substrate and adjacent to the active area; an inter-layer dielectric (ILD) over the isolation structure and the transistor; a first etch stop layer over a top surface of the ILD; a capacitor plate over the first etch stop layer; and an isolating portion over the capacitor plate, wherein the isolating portion has a first width, the capacitor plate has a second width, and the second width is smaller than the first width.

A disclosed high-density capacitor includes a top electrode having an electrically conducting material forming a three-dimensional structure. The three-dimensional structure includes a plurality of vertical portions extending in a vertical direction and horizontal portions, that are interleaved within the vertical portions and extend in a first horizontal direction. The high-density capacitor further includes a dielectric layer formed over the top electrode, and a bottom electrode including an electrically conducting material, such that the bottom electrode is separated from the top electrode by the dielectric layer. Further, the bottom electrode envelopes some of the plurality of vertical portions of the top electrode. The disclosed high-density capacitor further includes a plurality of support structures that are aligned with the first horizontal direction such that the horizontal portions of the top electrode are formed under respective support structures. The high-density capacitor has a capacitance that is proportional to the volume of the capacitor.

A ferroelectric device (100) that includes a metal nitride film (130) with favorable ferroelectricity is provided. The ferroelectric device comprises a first conductor (110), a metal nitride film over the first conductor, a second conductor (120) over the metal nitride film, a first insulator (155) over the second conductor, and a second insulator (152) over the first insulator. The first insulator includes regions in contact with the side surface of the metal nitride film and the side surface and the top surface of the second conductor; the metal nitride film has ferroelectricity; the metal nitride film contains a first element, a second element, and nitrogen; the first element is one or more elements selected from Group 13 elements; the second element is one or more elements selected from Group 2 elements to Group 6 elements and Group 13 elements other than the first element; the first conductor and the second conductor each contain nitrogen; the first insulator contains aluminum and oxygen; and the second insulator contains silicon and nitrogen.

The present disclosure relates to semiconductor structures and, more particularly, to a common-gate amplifier circuit and methods of operation. The structure includes at least one well in a substrate, a first metal layer connected to a gate of a transistor circuit, a second metal layer overlapped over the first metal layer to form a capacitor, and a third metal layer connected with vias to the first metal layer and overlapped with the second metal layer to form a second capacitor. At least one capacitance in at least one of a junction between the at least one well and the substrate and between overlapped metal layers of the first metal layer, the second metal layer, and the third metal layer.

A miniaturized transistor is provided. A transistor with low parasitic capacitance is provided. A transistor having high frequency characteristics is provided. A transistor having a large amount of on-state current is provided. A semiconductor device including the transistor is provided. A semiconductor device with high integration is provided. A novel capacitor is provided. The capacitor includes a first conductor, a second conductor, and an insulator. The first conductor includes a region overlapping with the second conductor with the insulator provided therebetween. The first conductor includes tungsten and silicon. The insulator includes a silicon oxide film that is formed by oxidizing the first conductor.

The present disclosure provides an ideal diode chip, including a first pin and a second pin arranged on a packaging frame. A power transistor and a first substrate are arranged on the first pin, and a switch transistor and a control module are arranged on the first substrate. The first pin serves as a cathode of the ideal diode chip, and the second pin serves as an anode of the ideal diode chip. The ideal diode chip according to the present disclosure can meet application requirements of different high voltage scenarios.

A semiconductor structure is provided that includes a tunable and shared non-conductive layer as part of a gate stack of at least a pair of nanosheet GAA transistors with a shared metal gate electrode. The semiconductor structure has a tunable non-conductive material/gate dielectric area ratio where the non-conductive material is not constrained to a periphery of the nanosheet stack cross section.

A back-side ground and power-distribution network is formed on a semiconductor wafer substrate by selectively etching first and second back-side partial-substrate rail (PSR) trench openings through a back-side surface of the wafer substrate, selectively forming a plurality of defined n-type conductive regions and defined p-type conductive regions in the wafer substrate at the bottoms of the first and second back-side PSR trench openings in position for electrical contact with n-well and p-well regions, and then forming first and second back-side PSR conductors in the first and second back-side PSR trench openings to be directly electrically connected over the plurality of defined n-type conductive regions and defined p-type conductive regions to the n-well and p-well regions in the wafer substrate.

The present disclosure provides, the semiconductor device includes a substrate, a first transistor, a capacitor, and two first plugs. The substrate has a high-voltage region and a capacitor region. The first transistor is disposed in the high-voltage region, and includes a first gate dielectric layer, a first gate electrode, and a first capping layer. The capacitor is disposed in the capacitor region and includes a second gate electrode, a second capping layer, a dielectric layer, and a conductive layer. The two first plugs are disposed on the capacitor, wherein one of the two first plugs penetrates through the second capping layer to directly contact the second gate electrode, and another one of the two first plugs directly contacts the conductive layer.

A semiconductor device includes a first region in which a passive element is provided, a second region adjacent to the first region and in which an active element is provided, a lower interlayer insulating layer in the first region and the second region, an insulating pattern in the second region and on an upper surface of the lower interlayer insulating layer, the insulating pattern extending in a first direction, a substrate in the first region, on the upper surface of the lower interlayer insulating layer, and spaced apart from the insulating pattern in the first direction, the substrate including silicon, and a field insulating layer in the second region and on the upper surface of the lower interlayer insulating layer, the field insulating layer at least partially surrounding a sidewall of the insulating pattern.