An integrated circuit structure may include a capacitor having a semiconductor layer as a first plate and a gate layer as a second plate. A capacitor dielectric layer may separate the first plate and the second plate. A backside metallization may be coupled to the first plate of the capacitor. A front-side metallization may be coupled to the second plate of the capacitor. The front-side metallization may be arranged distal from the backside metallization.

Various particular embodiments include a semiconductor varactor structure including: a semiconductor substrate of a first conductivity type; a semiconductor area of a second conductivity type, different from the first conductivity type, within the semiconductor substrate; a field effect transistor (FET) structure within the semiconductor area; and a contact, contacting the semiconductor area, for applying a voltage bias to the semiconductor area.

A capacitor includes an active layer, a gate insulation layer on the active layer, a gate electrode on the gate insulation layer, an interlayer insulating layer on the gate electrode, and a first electrode on the interlayer insulating layer and connected to the active layer through at least one contact hole.

A semiconductor device includes a substrate and a plurality of source/drain (S/D) regions in the substrate, wherein each of the plurality of S/D regions includes a first dopant having a first dopant type, and the each of the plurality of S/D regions are electrically coupled together. The semiconductor device further includes a gate stack over the substrate. The semiconductor device further includes a channel region in the substrate, wherein the channel region is below the gate stack and between adjacent S/D regions of the plurality of S/D regions, the channel region includes a second dopant having the first dopant type, and a concentration of the second dopant in the channel region is less than a concentration of the first dopant in each of the plurality of S/D regions.

Various embodiments of the present disclosure are directed towards a FinFET MOS capacitor. In some embodiments, the FinFET MOS capacitor comprises a substrate and a capacitor fin structure extending upwardly from an upper surface of the substrate. The capacitor fin structure comprises a pair of dummy source/drain regions separated by a dummy channel region and a capacitor gate structure straddling on the capacitor fin structure. The capacitor gate structure is separated from the capacitor fin structure by a capacitor gate dielectric.

An electronic device includes a semiconductor memory. The semiconductor memory may include a semiconductor substrate having an isolation trench in a first region and a capacitor trench in a second region, an isolation layer filling the isolation trench, an insulation layer pattern disposed along the capacitor trench, and a conductive layer pattern filling the capacitor trench over the insulation layer pattern. A capacitor includes a first portion of the semiconductor substrate in the second region, the insulation layer pattern, and the conductive pattern. A sidewall of the capacitor trench has a first angle with respect to a surface of the semiconductor substrate and a sidewall of the isolation trench has a second angle with respect to the surface of the semiconductor substrate. The first angle is more proximate to 90 degrees than the second angle.

A capacitor includes a silicon substrate, a conductor layer, and a dielectric layer. The silicon substrate has a principal surface including a capacitance generation region and a non-capacitance generation region. The silicon substrate includes a porous part provided in a thickness direction in the capacitance generation region. The conductor layer includes a surface layer part at least covering part of a surface of the capacitance generation region and a filling part filled in at least part of the porous part. The dielectric layer is provided between an inner surface of the porous part and the filling part. The porous part includes a macroporous part having macro pores and a nanoporous part formed in at least part of inner surfaces of the macro pores and having nano pores smaller than the macro pores.

A discrete capacitor of the present invention includes a substrate having a front surface portion, an impurity diffusion layer formed on the front surface portion of the substrate, an oxide film formed on the substrate and having a first opening to selectively expose the impurity diffusion layer, a dielectric film formed on the impurity region having been exposed from the oxide film, and a first electrode opposed to the impurity diffusion layer with the dielectric film therebetween, wherein the impurity concentration on the front surface portion of the impurity diffusion layer is 5×10.sup.19 cm.sup.−3 or more.

An example device in accordance with an aspect of the present disclosure includes at least one dielectric layer sandwiched between first and second layers, to provide a dielectric characteristic for the device. At least one interface layer, disposed between the at least one dielectric layer and at least one of i) the first layer, and ii) the second layer, is to serve as bond enhancement between the at least one dielectric layer and other layers.

Dual gate FD-SOI transistors are used as MOSFET capacitors to replace passive well capacitors in analog microcircuits. Use of the dual gate FD-SOI devices helps to reduce unstable oscillations and improve circuit performance. A thick buried oxide layer within the substrate of an FD-SOI transistor forms a capacitive dielectric that can sustain high operating voltages in the range of 1.2 V-3.3 V, above the transistor threshold voltage. A secondary gate in the FD-SOI transistor is used to create a channel from the back side so that even when the bias voltage on the first gate is small, the effective capacitance remains higher. The capacitance of the buried oxide layer is further utilized as a decoupling capacitor between supply and ground. In one example, a dual gate PMOS FD-SOI transistor is coupled to an operational amplifier and a high voltage output driver to produce a precision-controlled voltage reference generator. In another example, two dual gate PMOS and one dual gate NMOS FD-SOI transistor are coupled to a charge pump, a phase frequency detector, and a current-controlled oscillator to produce a high-performance phase locked loop circuit in which the decoupling capacitor footprint is smaller, in comparison to the conventional usage of passive well capacitance.