One-dimensional and two-dimensional arrays of qubits are disclosed. The one-dimensional array includes two or more double-quantum dots embedded in silicon, the two or more double-quantum dots arranged in an Echelon formation, such that the distance between the two or more double-quantum dots is approximately 40 nm and the distance between the two quantum dots in each double-quantum dot is approximately 12 nm; two or more reservoirs to load electrons to the corresponding two or more double-quantum dots to form singlet-triplet qubits in each double-quantum dot; and two or more gates for controlling the formed singlet-triplet qubits. The two-dimensional array of qubits includes two or more layers of vertically-stacked one-dimensional arrays of qubits.

The present disclosure relates to semiconductor structures and, more particularly, to vertical bipolar transistors and methods of manufacture. The structure includes: an intrinsic base region comprising semiconductor-on-insulator material; a collector region confined within an insulator layer beneath the semiconductor-on-insulator material; an emitter region above the intrinsic base region; and an extrinsic base region above the intrinsic base region.

Provided is a semiconductor device including: a semiconductor substrate having an upper surface and a lower surface and having a drift region of a first conductivity type; a first main terminal provided above the upper surface; a second main terminal provided below the lower surface; a control terminal configured to control whether or not to cause a current to flow between the first main terminal and the second main terminal; and a buffer region provided between the drift region and the lower surface and having a higher doping concentration than the drift region. In a C-V characteristic indicating a relationship between a power supply voltage applied between the first main terminal and the second main terminal and an inter-terminal capacitance between the control terminal and the second main terminal, a region where the power supply voltage is 500 V or more has a peak of the inter-terminal capacitance.

A MOS transistor structure is provided. The MOS transistor structure includes a semiconductor substrate having an active area including a first edge and a second edge opposite thereto. A gate layer is disposed on the active area of the semiconductor substrate and has a first edge extending across the first and second edges of the active area. A source region having a first conductivity type is in the active area at a side of the first edge of the gate layer and between the first and second edges of the active area. First and second heavily doped regions of a second conductivity type are in the active area adjacent to the first and second edges thereof, respectively, and spaced apart from each other by the source region.

A gate-turn-off thyristor is provided. The gate-turn-off thyristor includes a plurality of strips formed by repeatedly arranging a plurality of N-type emitter regions with high doping concentration of an upper transistor on an upper surface of an N-type silicon substrate with high resistivity, wherein a periphery of each strip of the plurality of strips is surrounded with a P-type dense base region bus bar of the upper transistor, a cathode metal layer is disposed on an N-type emitter region of the plurality of N-type emitter regions of the upper transistor, and a P-type base region of the upper transistor is disposed below the N-type emitter region of the upper transistor; a side of the P-type base region of the upper transistor is connected to a P-type dense base region of the upper transistor or a P-type dense base region bus bar of the upper transistor.

An apparatus includes a substrate and a transistor disposed on the substrate. The transistor includes a source and a source contact disposed on the source. The transistor also includes a drain and a drain contact disposed on the drain. A gate is disposed between the source contact and the drain contact, and a screened region is disposed adjacent the source contact or the drain contact. The screened region corresponds to a lightly doped region. The screened region includes an implant screen configured to reduce an effective dose in the screened region so as to shift an acceptable dose range of the screened region to a higher dose range. The acceptable dose range corresponds to acceptable breakdown voltage values for the screened region.

A lateral double-diffused metal-oxide-semiconductor (LDMOS) transistor including a breakdown voltage clamp includes a drain n+ region, a source n+ region, a gate, and a p-type reduced surface field (PRSF) layer including one or more bridge portions. Each of the one or more bridge portions extends below the drain n+ region in a thickness direction. Another LDMOS transistor includes a drain n+ region, a source n+ region, a gate, an n-type reduced surface field (NRSF) layer disposed between the source n+ region and the drain n+ region in a lateral direction, a PRSF layer disposed below the NRSF layer in a thickness direction orthogonal to the lateral direction, and a p-type buried layer (PBL) disposed below the PRSF layer in the thickness direction. The drain n+ region is disposed over the PBL in the thickness direction.

A lateral double-diffused metal oxide semiconductor field effect transistor (LDMOS), including: a trench gate including a lower part inside a trench and an upper part outside the trench, a length of the lower part in a width direction of a conducting channel being less than that of the upper part, and the lower part extending into a body region and having a depth less than that of the body region; an insulation structure arranged between a drain region and the trench gate and extending downwards into a drift region, a depth of the insulation structure being less than that of the drift region.

A high electron mobility transistor includes a channel layer; a barrier layer on the channel layer and having an energy bandgap greater than an energy bandgap of the channel layer; a gate structure on the barrier layer; a source electrode and a drain electrode spaced apart from each other on the barrier layer with the gate structure therebetween; a field plate electrically connected to the source electrode and extending above the gate structure; and a field dispersion layer in contact with the barrier layer and the drain electrode. The field dispersion layer may extend toward the gate structure.

The present disclosure relates to the technical field of semiconductors, and provides an electro-static discharge (ESD) protection structure and a chip. The ESD protection structure includes: a semiconductor substrate, a first P-type well, a first N-type well, a first N-type doped portion, a first P-type doped portion, a second N-type doped portion, a second P-type doped portion, a third doped well, a third P-type doped portion and a third N-type doped portion, wherein the first P-type well, the first N-type well and the third doped well are located in the semiconductor substrate; the first N-type doped portion and the first P-type doped portion are located in the first N-type well and spaced apart; the second N-type doped portion and the second P-type doped portion are located in the first P-type well and spaced apart.