The various embodiments described herein include methods, devices, and systems for fabricating and operating photodetector circuitry. In one aspect, a photon detector system includes: (1) a first superconducting wire having a first threshold superconducting current; (2) a second superconducting wire having a second threshold superconducting current; (3) a resistor coupled to the first wire and the second wire; (4) current source(s) coupled to the first wire and configured to supply a current that is below the second threshold current; and (3) a second circuit coupled to the second wire. In response to receiving light at the first wire, the first wire transitions from a superconducting state to a non-superconducting state. In response to receiving light at the second wire while the first wire is in the non-superconducting state, the second wire transitions to a non-superconducting state, redirecting the first current to the second circuit.

The various embodiments described herein include methods, devices, and systems for fabricating and operating photodetector circuitry. In one aspect, a photon detector system includes: (1) a first superconducting wire having a first threshold superconducting current; (2) a second superconducting wire having a second threshold superconducting current; (3) a resistor coupled to the first wire and the second wire; (4) current source(s) coupled to the first wire and configured to supply a current that is below the second threshold current; and (3) a second circuit coupled to the second wire. In response to receiving light at the first wire, the first wire transitions from a superconducting state to a non-superconducting state. In response to receiving light at the second wire while the first wire is in the non-superconducting state, the second wire transitions to a non-superconducting state, redirecting the first current to the second circuit.

In one disclosed embodiment, a non-volatile memory cell is constructed using a floating gate transistor with a channel that includes a buried channel region interposed between two surface channel regions under a floating gate. The surface channel regions are formed using angled lightly-doped drain implantation at locations in the substrate so that a first surface channel region is located under a first end of the floating gate and a second surface channel region is located under a second end of the floating gate. In one embodiment, the floating gate transistor is a PMOS transistor, with the channel being formed in an n-well formed in a p-type substrate, with the buried channel region being formed using a Vtp implant, and with the surface channel regions being formed using angled NLDD implants. The surface channel regions increase the energy barrier along the channel and reduce off state current of the memory cell.

A heterojunction bipolar transistor includes a collector layer, a base layer, an emitter layer, and a semiconductor layer that are laminated in this order, wherein the emitter layer includes a first region having an upper surface on which the semiconductor layer is laminated, and a second region being adjacent to the first region and having an upper surface that is exposed, and the first and second regions of the emitter layer have higher doping concentrations in portions near the upper surfaces than in portions near an interface between the emitter layer and the base layer.

The present disclosure is directed toward carbon based diodes, carbon based resistive change memory elements, resistive change memory having resistive change memory elements and carbon based diodes, methods of making carbon based diodes, methods of making resistive change memory elements having carbon based diodes, and methods of making resistive change memory having resistive change memory elements having carbons based diodes. The carbon based diodes can be any suitable type of diode that can be formed using carbon allotropes, such as semiconducting single wall carbon nanotubes (s-SWCNT), semiconducting Buckminsterfullerenes (such as C60 Buckyballs), or semiconducting graphitic layers (layered graphene). The carbon based diodes can be pn junction diodes, Schottky diodes, other any other type of diode formed using a carbon allotrope. The carbon based diodes can be placed at any level of integration in a three dimensional (3D) electronic device such as integrated with components or wiring layers.

The present disclosure is directed toward carbon based diodes, carbon based resistive change memory elements, resistive change memory having resistive change memory elements and carbon based diodes, methods of making carbon based diodes, methods of making resistive change memory elements having carbon based diodes, and methods of making resistive change memory having resistive change memory elements having carbons based diodes. The carbon based diodes can be any suitable type of diode that can be formed using carbon allotropes, such as semiconducting single wall carbon nanotubes (s-SWCNT), semiconducting Buckminsterfullerenes (such as C60 Buckyballs), or semiconducting graphitic layers (layered graphene). The carbon based diodes can be pn junction diodes, Schottky diodes, other any other type of diode formed using a carbon allotrope. The carbon based diodes can be placed at any level of integration in a three dimensional (3D) electronic device such as integrated with components or wiring layers.

A change in electrical characteristics of a semiconductor device including an interlayer insulating film over a transistor including an oxide semiconductor as a semiconductor film is suppressed. The structure includes a first insulating film which includes a void portion in a step region formed by a source electrode and a drain electrode over the semiconductor film and contains silicon oxide as a component, and a second insulating film containing silicon nitride, which is provided in contact with the first insulating film to cover the void portion in the first insulating film. The structure can prevent the void portion generated in the first insulating film from expanding outward.

Methods of forming self-aligned gate contacts and cross-coupling contacts for field-effect transistors and structures for field effect-transistors that include self-aligned gate contacts and cross-coupling contacts. A sidewall spacer is formed at a sidewall of a gate structure and an epitaxial semiconductor layer is formed adjacent to the sidewall spacer. After forming the epitaxial semiconductor layer, the sidewall spacer is recessed with a first etching process. After recessing the spacer, the gate structure is recessed with a second etching process. After recessing the gate structure, a cross-coupling contact is formed that connects the gate structure with the epitaxial semiconductor layer.

A semiconductor device and a method of forming the same are disclosed. The semiconductor device includes a semiconductor substrate; a fin extending from the semiconductor substrate; a first charged dielectric layer covering a bottom portion of the fin, the first charged dielectric layer having net fixed first-type charges; a second charged dielectric layer covering the first charged dielectric layer, the second charged dielectric layer having net fixed second-type charges, the second-type charges being opposite to the first-type charges; and a gate structure engaging a top portion of the fin.

A method of forming a nanostructure comprises forming a directed self-assembly of nucleic acid structures on a patterned substrate. The patterned substrate comprises multiple regions. Each of the regions on the patterned substrate is specifically tailored for adsorption of specific nucleic acid structure in the directed self-assembly.