An LDMOS device comprises a well region, first and second implant regions, a gate electrode, first and second source/drain regions, a first STI region, and a first DTI region. The well region is in a substrate and of a first conductivity type. The first implant region is in the substrate and of a second conductivity type. The second implant region is in the well region and of the first conductivity type. The gate electrode extends from above the well region to above the first implant region. The first and second source/drain regions are respectively in the first and second implant regions. The first STI region laterally extends from the second implant region to directly below the gate electrode. The first DTI region extends downwards from a bottom surface of the first STI region into the well region. The first DTI region vertically overlaps with the gate electrode.

Embodiments of the present disclosure describe a method of fabricating spin qubit device assemblies that utilize dopant-based spin qubits, i.e. spin qubit devices which operate by including a donor or an acceptor dopant atom in a semiconductor host layer. The method includes, first, providing a pair of gate electrodes over a semiconductor host layer, and then providing a window structure between the first and second gate electrodes, the window structure being a continuous solid material extending between the first and second electrodes and covering the semiconductor host layer except for an opening through which a dopant atom is to be implanted in the semiconductor host layer. By using a defined gate-first process, the method may address the scalability challenges and create a deterministic path for fabricating dopant-based spin qubits in desired locations, promoting wafer-scale integration of dopant-based spin qubit devices for use in quantum computing devices.

A semiconductor device includes a substrate, an epitaxial layer, an emitter region, and a collector region. The epitaxial layer is disposed over the substrate and has a first conductivity type. The drift region is disposed in the epitaxial layer and has a second conductivity type that is the opposite of the first conductivity type. The emitter region is disposed in the epitaxial layer outside the drift region. The collector region is disposed in the drift region. The semiconductor device also includes a doped region. The doped region is disposed adjacent to the bottom surface of the drift region and has the first conductivity type.

Vertical etch heterolithic integrated circuit devices are described. A method of manufacturing NIP diodes is described in one example. A P-type substrate is provided, and an intrinsic layer is formed on the P-type substrate. An oxide layer is formed on the intrinsic layer, and one or more openings are formed in the oxide layer. One or more N-type regions are implanted in the intrinsic layer through the openings in the oxide layer. The N-type regions form cathodes of the NIP diodes. A dielectric layer deposited over the oxide layer is selectively etched away with the oxide layer to expose certain ranges of the intrinsic layer to define a geometry of the NIP diodes. The intrinsic layer and the P-type substrate are vertically etched away within the ranges to expose sidewalls of the intrinsic layer and the P-type substrate. The P-type substrate forms the anodes of the NIP diodes.

A device includes a substrate, a drift region in the substrate, a base region above the drift region; a first high concentration region selectively formed in a part on a surface side of the base region and having a concentration higher than the drift region; a trench portion formed in a front surface of the substrate and including extending portions; and mesa portions between the extending portions. The mesa portions includes first mesa portions having the first high concentration region and second mesa portions not having the first high concentration region, the trench portion includes a first trench portion having an first conductive portion (a gate conductive potion) and adjacent to the first mesa portion, a second trench portion having the first conductive portion and adjacent to the second mesa portion, and a third trench portion having an second conductive portion and adjacent to the first or second mesa portion.

The present disclosure provides a semiconductor structure and a manufacturing method thereof. The manufacturing method of a semiconductor structure includes: providing an initial semiconductor structure, where the initial semiconductor structure includes a substrate and a polycrystalline silicon layer; forming a first mask layer on the initial semiconductor structure, where the first mask layer has a first ion implantation window, and the first ion implantation window defines a position of a gate electrode of a first transistor; and performing a first ion implantation process to perform work function adjustment on the gate electrode of the first transistor through the first ion implantation window, to form a semiconductor structure.

A method for making an LDMOS device including forming a first ion doped region in an epitaxial layer of a first region and removing a first oxide layer of the first region, the first oxide layer being formed on the epitaxial layer; forming a second oxide layer on the epitaxial layer and the remaining first oxide layer; forming a second ion doped region in the epitaxial layer of a second region, the first region and the second region having no overlapped region; and forming a polysilicon layer on the second oxide layer; removing the polysilicon layer, the first oxide layer and the second oxide layer of a third region.

A quantum device with spin qubits, comprising: a semiconductor portion arranged on a buried dielectric layer of a semiconductor-on-insulator substrate also including a semiconductor support layer, wherein first distinct parts each form a confinement region of one of the qubits and are spaced apart from one another by a second part forming a coupling region between the confinement regions of the qubits; front gates each at least partially covering one of the first parts of the semiconductor portion; and wherein the support layer comprises a doped region a part of which is arranged in line with the second part of the semiconductor portion and is self-aligned with respect to the front gates, and forms a back gate controlling the coupling between the confinement regions of the qubits.

A method for fabricating p-type field effect transistor (FET) includes the steps of first providing a substrate, forming a pad layer on the substrate, forming a well in the substrate, performing an ion implantation process to implant germanium ions into the substrate to form a channel region, and then conducting an anneal process to divide the channel region into a top portion and a bottom portion. After removing the pad layer, a gate structure is formed on the substrate and a lightly doped drain (LDD) is formed adjacent to two sides of the gate structure.

Disclosed herein are approaches for reducing buried channel recess depth using a non-doping ion implant prior to formation of the buried channel. In one approach, a method may include providing an oxide layer over a substrate, performing a non-doping implantation process through the oxide layer to form an amorphous region in the substrate, and forming a photoresist over the oxide layer. The method may further include forming a buried layer in the substrate by implanting the substrate through an opening in the photoresist, and performing an oxidation and dopant drive-in process to the amorphous region and to the buried layer to form a second oxide layer.