Subject matter disclosed herein may relate to programmable fabrics including correlated electron switch devices.

A semiconductor device includes a first varactor diode and a second varactor diode. The second varactor diode is coupled in series with the first varactor diode and vertically disposed over the first varactor diode. By vertically disposing the second varactor diode over the first varactor diode, the space occupied by the pair of varactor diodes can be significantly reduced.

A semiconductor component, in particular for a varactor, having at least one first semiconductor layer and a second semiconductor layer. At least two identical surface electrodes are arranged directly or indirectly on the second semiconductor layer facing away from the first semiconductor layer in order to form two anti-serially connected diodes. The surface electrodes are arranged in an interacting manner such that a load carrier zone which forms the common counter electrode for the surface electrodes is arranged in the first semiconductor layer at least in the operating state, and at least one control contact for controlling the potential of the load carrier zone is provided in a region of the load carrier zone on the second semiconductor layer face facing away from the first semiconductor layer. The load carrier zone produces a continuous electric connection from the counter electrode to the at least one control contact at least in the operating state, and the load carrier zone protrudes beyond the surface electrodes in a projection onto the rear face of the semiconductor component.

Subject matter disclosed herein may relate to programmable fabrics including correlated electron switch devices.

An accumulation-mode MOS varactor is formed with a standard CMOS process and having an anti-symmetric-CV curve. The asymmetric varactor (ASVAR) can efficiently generate even-order harmonics while simultaneously suppressing odd-order harmonics over broad bandwidths. This is achieved without degradation of dynamic cut-off frequency. The improved cut-off frequency of the asymmetric varactor results in efficient even-harmonic generation well into sub-millimeter or terahertz frequencies. This and the inherent adaptive-CV features of the asymmetric varactor result in even-harmonic generation with process variation resilience and can also be utilized for frequency response shaping and for optimizing performance at various driving conditions.

Various embodiments of the present disclosure are directed towards a varactor comprising a reduced surface field (RESURF) region. In some embodiments, the varactor includes a drift region, a gate structure, a pair of contact regions, and a RESURF region. The drift region is within a substrate and has a first doping type. The gate structure overlies the drift region. The contact regions are within the substrate and overlie the drift region. Further, the contact regions have the first doping type. The gate structure is laterally sandwiched between the contact regions. The RESURF region is in the substrate, below the drift region, and has a second doping type. The second doping type is opposite the first doping type. The RESURF region aids in depleting the drift region under the gate structure, which decreases the minimum capacitance of the varactor and increases the tuning range of the varactor.

A device includes a first capacitor and a second capacitor connected to the first capacitor in parallel. The first capacitor includes a semiconductor region and a first plurality of gate stacks. The first plurality of gate stacks comprise a plurality of gate dielectrics over and contacting the semiconductor region, and a plurality of gate electrodes over the plurality of gate dielectrics. The second capacitor includes an isolation region, a second plurality of gate stacks over the isolation region, and a plurality of conductive strips over the isolation region and parallel to the second plurality of gate stacks. The second plurality of gate stacks and the plurality of conductive strips are laid out alternatingly.

An integrated circuit structure comprises one or more fins extending above a surface of a substrate over an N-type well. A gate is over and in contact with the one or more fins. A second shallow N-type doping is below the gate and above the N-type well.

Aspects of the present disclosure provide semiconductor variable capacitor devices. In one embodiment, a semiconductor variable capacitor includes a gate oxide layer comprising a first layer portion with a first thickness and a second layer portion with a second thickness; a first non-insulative region disposed above the gate oxide layer; a first semiconductor region disposed beneath the gate oxide layer; a second semiconductor region disposed beneath the gate oxide layer and adjacent to the first semiconductor region, wherein the second semiconductor region comprises a different doping type than the first semiconductor region a second non-insulative region coupled to the first semiconductor region; and a control terminal coupled to a control region coupled to the second semiconductor region such that a first capacitance between the first non-insulative region and the second non-insulative region is configured to be adjusted by varying a control voltage applied to the control region.

A capacitor may include a first conductive layer forming a first capacitor plate, a second conductive layer forming a second capacitor plate, and a first insulating material on the first conductive layer. The first insulating material may include a positive capacitance material. The capacitor may further include a second insulating material disposed over the first insulating material and between the first insulating material and the second conductive layer. The second insulating material may include a negative capacitance ferroelectric material.