A superconductor magnetic field effect transistor. The superconductor magnetic field effect transistor may include a sheet of a superconducting material; and a solenoid. The sheet may be substantially flat, and the solenoid may include a plurality of turns, each of the turns being substantially parallel to the sheet. The superconducting material may be a type-II superconducting material.

Superconducting Meissner effect transistors, methods of modulating, and systems are disclosed. In one aspect a disclosed transistor includes a superconducting bridge between a first and a second current probe, the first and second current probe being electrically connected to a source and a drain electrical connection, respectively and a control line configured to emit a magnetic field signal having signal strength H.sub.sig at the superconducting bridge. In one aspect the emitted magnetic field is configured to break Cooper pairs in the superconducting bridge.

A transistor includes (i) a first wire including a semiconducting component configured to operate in an on state at temperatures above a semiconducting threshold temperature and (ii) a second wire including a superconducting component configured to operate in a superconducting state while: a temperature of the superconducting component is below a superconducting threshold temperature and a first input current supplied to the superconducting component is below a current threshold. The semiconducting component is located adjacent to the superconducting component. In response to a first input voltage, the semiconducting component is configured to generate an electromagnetic field sufficient to lower the current threshold such that the first input current exceeds the lowered current threshold.

Stacked superconducting integrated circuits with three dimensional resonant clock networks are described. An apparatus, including a first superconducting integrated circuit having a first clock distribution network for distributing a first clock signal in the first superconducting integrated circuit, is provided. The apparatus further includes a second superconducting integrated circuit, stacked on top of the first superconducting integrated circuit, having a second clock distribution network for distributing a second clock signal in the second superconducting integrated circuit, where each of the first clock distribution network and the second clock distribution network comprises a clock structure having a plurality of unit cells, where each of the plurality of unit cells includes at least one spine and at least one stub, the at least one stub inductively coupled to a first superconducting circuit, and where each of the first clock signal and the second clock signal has a same resonant frequency.

Stacked superconducting integrated circuits with three dimensional resonant clock networks are described. An apparatus, including a first superconducting integrated circuit having a first clock distribution network for distributing a first clock signal in the first superconducting integrated circuit, is provided. The apparatus further includes a second superconducting integrated circuit, stacked on top of the first superconducting integrated circuit, having a second clock distribution network for distributing a second clock signal in the second superconducting integrated circuit, where each of the first clock distribution network and the second clock distribution network comprises a clock structure having a plurality of unit cells, where each of the plurality of unit cells includes at least one spine and at least one stub, the at least one stub inductively coupled to a first superconducting circuit, and where each of the first clock signal and the second clock signal has a same resonant frequency.

Disclosed herein are quantum dot devices, as well as related computing devices and methods. For example, in some embodiments, a quantum dot device may include: a quantum well stack including a quantum well layer and a barrier layer; a first gate metal above the quantum well stack, wherein the barrier layer is between the first gate metal and the quantum well layer; and a second gate metal above the quantum well stack, wherein the barrier layer is between the second gate metal and the quantum well layer, and a material structure of the second gate metal is different from a material structure of the first gate metal.

The invention is notably directed to a method of operating a superconducting channel. The method relies on a device including: a potentially superconducting material; a gate electrode; and an electrically insulating medium. A channel is defined by the potentially superconducting material. The gate electrode positioned adjacent to the channel, such that an end surface of the gate electrode faces a portion of the channel. The electrically insulating medium is arranged in such a manner that it electrically insulates the gate electrode from the channel. Rendering the channel superconducting by cooling down the device. Next, a voltage difference is applied between the gate electrode and the channel to inject electrons in the channel through the electrically insulating medium and thereby generate a gate current between the gate electrode and the channel. The electrons are injected with an average energy sufficient to modify a critical current I.sub.C of the channel.

The various embodiments described herein include methods, devices, and systems for fabricating and operating transistors. In one aspect, a transistor includes: (1) a semiconducting component configured to operate in an on state at temperatures above a semiconducting threshold temperature; and (2) a superconducting component configured to operate in a superconducting state while: (a) a temperature of the superconducting component is below a superconducting threshold temperature; and (b) a first current supplied to the superconducting component is below a current threshold; where: (i) the semiconducting component is located adjacent to the superconducting component; and (ii) in response to a first input voltage, the semiconducting component is configured to generate an electromagnetic field sufficient to lower the current threshold such that the first current exceeds the lowered current threshold, thereby transitioning the superconducting component to a non-superconducting state.

A transistor includes (i) a first wire including a semiconducting component configured to operate in an on state at temperatures above a semiconducting threshold temperature and (ii) a second wire including a superconducting component configured to operate in a superconducting state while: a temperature of the superconducting component is below a superconducting threshold temperature and a first input current supplied to the superconducting component is below a current threshold. The semiconducting component is located adjacent to the superconducting component. In response to a first input voltage, the semiconducting component is configured to generate an electromagnetic field sufficient to lower the current threshold such that the first input current exceeds the lowered current threshold.

The invention is notably directed to a method of operating a superconducting channel. The method relies on a device including: a potentially superconducting material; a gate electrode; and an electrically insulating medium. A channel is defined by the potentially superconducting material. The gate electrode positioned adjacent to the channel, such that an end surface of the gate electrode faces a portion of the channel. The electrically insulating medium is arranged in such a manner that it electrically insulates the gate electrode from the channel. Rendering the channel superconducting by cooling down the device. Next, a voltage difference is applied between the gate electrode and the channel to inject electrons in the channel through the electrically insulating medium and thereby generate a gate current between the gate electrode and the channel. The electrons are injected with an average energy sufficient to modify a critical current I.sub.C of the channel.