A novel and useful quantum computing machine includes classic computing and quantum computing cores. A programmable pattern generator executes instructions that control the quantum core. A pulse generator generates the control signals input to the quantum core to perform quantum operations. A partial readout of the quantum state is re-injected into the quantum core to extend decoherence time. Access gates control movement of quantum particles in the quantum core. Errors are corrected from the readout before being re-injected into the quantum core. Internal and external calibration loops calculate error syndromes and calibrate control pulses input to the quantum core. Control of the quantum core is provided from an external support unit via the pattern generator or retrieved from classic memory where sequences of commands are stored in memory. A cryostat unit functions to cool the quantum computing core to approximately 4 Kelvin.

A semiconductor device includes a semiconductor substrate including a barrier region, a channel layer disposed below the barrier region and forming a heterojunction with the barrier region such that a two-dimensional charge carrier gas channel is disposed in the channel layer near the heterojunction, and a sub-channel region disposed below the channel layer, and a first interface in the semiconductor substrate between a first region of type III-V material and a second region of type III-V material that is disposed below the first region of type III-V material, wherein the first and second regions of type III-V material form polarization charges on either side of the first interface, wherein the first interface is within or formed by the sub-channel region, and wherein semiconductor substrate has a vertically varying dopant concentration of deep energy acceptor dopant atoms that is locally increased at the first interface.

A method for making a semiconductor gate-all-around (GAA) device may include forming source and drain regions on a semiconductor substrate, forming a plurality of semiconductor nanostructures extending between the source and drain regions, forming a gate surrounding the plurality of semiconductor nanostructures in a gate-all-around arrangement, and forming a dopant diffusion liner adjacent at least one of the source and drain regions and comprising a first superlattice. The first superlattice may include a plurality of stacked groups of layers, with each group of layers including a plurality of stacked base semiconductor monolayers defining a base semiconductor portion, and at least one non-semiconductor monolayer constrained within a crystal lattice of adjacent base semiconductor portions.

Novel and useful quantum structures having a continuous well with control gates that control a local depletion region to form quantum dots. Local depleted well tunneling is used to control quantum operations to implement quantum computing circuits. Qubits are realized by modulating gate potential to control tunneling through local depleted region between two or more sections of the well. Complex structures with a higher number of qdots per continuous well and a larger number of wells are fabricated. Both planar and 3D FinFET semiconductor processes are used to build well to gate and well to well tunneling quantum structures. Combining a number of elementary quantum structure, a quantum computing machine is realized. An interface device provides an interface between classic circuitry and quantum circuitry by permitting tunneling of a single quantum particle from the classic side to the quantum side of the device. Detection interface devices detect the presence or absence of a particle destructively or nondestructively.

A semiconductor layer stack, a component made therefrom, a component module, and a production method is provided. The semiconductor layer stack has at least two layers (A, B), which, as individual layers, each have an energy position of the Fermi level in the semiconductor band gap, $E_F-E_V<\frac{E_G}{2}$
applying to the layer (A) and $E_L-E_F<\frac{E_G}{2}$
applying to the layer (B), with E.sub.F the energy position of the Fermi level, E.sub.V the energy position of the valence band, E.sub.L the energy position of a conduction band and E.sub.L−E.sub.V the energy difference of the semiconductor band gap E.sub.G, the thickness of the layers (A, B) being selected in such a way that a continuous space charge zone region over the layers (A, B) results.

A semiconductor device includes a substrate, a first GaN-based high-electron-mobility transistor (HEMT), a second GaN-based HEMT, a first interconnection, and a second interconnection is provided. The substrate has a plurality of first-type doped semiconductor regions and second-type doped semiconductor regions. The first GaN-based HEMT is disposed over the substrate to cover a first region on the first-type doped semiconductor regions and the second-type doped semiconductor regions in the substrate. The second GaN-based HEMT is disposed over the substrate to cover a second region. The first region is different from the second region. The first interconnection is disposed over and electrically connected to the substrate, forming a first interface. The second interconnection is disposed over and electrically connected to the substrate, forming a second interface. The first interface is separated from the second interface by at least two heterojunctions formed in the substrate.

A semiconductor structure includes a substrate. The semiconductor structure further includes a first III-V layer over the substrate, wherein the first III-V layer includes a first dopant type. The semiconductor structure further includes a second III-V layer over the first III-V layer, wherein the second III-V layer has a second dopant type opposite the first dopant type. The semiconductor structure further includes a third III-V layer over the second III-V layer, wherein the third III-V layer has the first dopant type. The semiconductor structure further includes a fourth III-V layer over the third III-V layer, the fourth III-V layer having the second dopant type. The semiconductor structure further includes an active layer over the fourth III-V layer. The semiconductor structure further includes a dielectric layer over the active layer.

The present disclosure provides a semiconductor device and a fabricating method thereof, the semiconductor device including a substrate, a nucleation layer, a buffer layer, an active layer and a gate electrode. The nucleation layer is disposed on the substrate, and the buffer layer is disposed on the nucleation layer, wherein the buffer layer includes a first superlattice layer having at least two heteromaterials alternately arranged in a horizontal direction, and a second superlattice layer having at least two heteromaterials vertically stacked along a vertical direction. The at least two heteromaterials stack at least once within the second superlattice layer. The active layer is disposed on the buffer layer, and the gate electrode is disposed on the active layer.

A semiconductor device includes a semiconductor substrate including a barrier region, a channel layer disposed below the barrier region and forming a heterojunction with the barrier region such that a two-dimensional charge carrier gas channel is disposed in the channel layer near the heterojunction, and a sub-channel region disposed below the channel layer, and a first interface in the semiconductor substrate between a first region of type III-V material and a second region of type III-V material that is disposed below the first region of type III-V material, wherein the first and second regions of type III-V material form polarization charges on either side of the first interface, wherein the first interface is within or formed by the sub-channel region, and wherein semiconductor substrate has a vertically varying dopant concentration of deep energy acceptor dopant atoms that is locally increased at the first interface.

A semiconductor device includes; a substrate including a first region and a second region, a first active pattern extending upward from the first region, a first superlattice pattern on the first active pattern, a first active fin centrally disposed on the first active pattern, a first gate electrode disposed on the first active fin, and first source/drain patterns disposed on opposing sides of the first active fin and on the first active pattern. The first superlattice pattern includes at least one first semiconductor layer and at least one first blocker-containing layer, and the first blocker-containing layer includes at least one of oxygen, carbon, fluorine and nitrogen.