Semiconductor device and the manufacturing method thereof are disclosed. An exemplary method comprises forming a first stack structure and a second stack structure in a first area over a substrate, wherein each of the stack structures includes semiconductor layers separated and stacked up; depositing a first interfacial layer around each of the semiconductor layers of the stack structures; depositing a gate dielectric layer around the first interfacial layer; forming a dipole oxide layer around the gate dielectric layer; removing the dipole oxide layer around the gate dielectric layer of the second stack structure; performing an annealing process to form a dipole gate dielectric layer for the first stack structure and a non-dipole gate dielectric layer for the second stack structure; and depositing a first gate electrode around the dipole gate dielectric layer of the first stack structure and the non-dipole gate dielectric layer of the second stack structure.

An oxide semiconductor layer which is intrinsic or substantially intrinsic and includes a crystalline region in a surface portion of the oxide semiconductor layer is used for the transistors. An intrinsic or substantially intrinsic semiconductor from which an impurity which is to be an electron donor (donor) is removed from an oxide semiconductor and which has a larger energy gap than a silicon semiconductor is used. Electrical characteristics of the transistors can be controlled by controlling the potential of a pair of conductive films which are provided on opposite sides from each other with respect to the oxide semiconductor layer, each with an insulating film arranged therebetween, so that the position of a channel formed in the oxide semiconductor layer is determined.

The present disclosure relates to a nanowire structure, which includes a substrate with a substrate body and an ion implantation region, a patterned mask with an opening over the substrate, and a nanowire. Herein, the substrate body is formed of a conducting material, and the ion implantation region that extends from a top surface of the substrate body into the substrate body is electrically insulating. A surface portion of the substrate body is exposed through the opening of the patterned mask, while the ion implantation region is fully covered by the patterned mask. The nanowire is directly formed over the exposed surface portion of the substrate body and is not in contact with the ion implantation region. Furthermore, the nanowire is confined within the ion implantation region, such that the ion implantation region is configured to provide a conductivity barrier of the nanowire in the substrate.

Embodiments herein relate to vertical contacts for semiconductor devices. For instance, a memory device having vertical contacts can comprise a substrate including circuitry components, a vertical stack of layers formed from repeating iterations of a group of layers disposed on the substrate, the group of layers comprising a first dielectric material layer, a semiconductor material layer, and a second dielectric material layer including horizontal conductive lines formed along a horizontal plane in the second dielectric material layer, and vertical contacts coupled to the horizontal conductive lines, the vertical contacts extending along a vertical plane within the vertical stack of layers to directly electrically couple the horizontal conductive lines to the circuitry components.

Techniques are disclosed for non-planar transistors having varying channel widths (Wsi). In some instances, the resulting structure has a fin (or nanowires, nanoribbons, or nanosheets) comprising a first channel region and a second channel region, with a source or drain region between the first channel region and the second channel region. The widths of the respective channel regions are independent of each other, e.g., a first width of the first channel region is different from a second width of the second channel region. The variation in width of a given fin structure may vary in a symmetric fashion or an asymmetric fashion. In an embodiment, a spacer-based forming approach is utilized that allows for abrupt changes in width along a given fin. Sub-resolution fin dimensions are achievable as well.

A resistor includes a substrate including an active region protruding from an upper surface of the substrate and extending in a first horizontal direction, a doped region extending in the first horizontal direction on the active region and comprising a semiconductor layer with n-type impurities, a plurality of channel layers spaced apart from each other in a vertical direction on the active region and connected to the doped region, a first gate electrode and a second gate electrode extending in the second horizontal direction intersecting the first horizontal direction and surrounding the plurality of channel layers, a first contact plug and a second contact plug in contact with an upper surface of the doped region. The first contact plug is adjacent to the first gate electrode. The second contact plug is adjacent to the second gate electrode.

Provided is a semiconductor structure with shared gated devices. The semiconductor structure comprises a substrate and a bottom dielectric isolation (BDI) layer on top of the substrate. The structure further comprises a pFET region that includes a p-doped Source-Drain epitaxy material and a first nanowire matrix above the BDI layer. The structure further comprises an nFET region that includes a n-doped Source-Drain epitaxy material and a second nanowire matrix above the BDI layer. The structure further comprises a conductive gate material on top of a portion of the first nanowire matrix and the second nanowire matrix. The structure further comprises a vertical dielectric pillar separating the pFET region and the nFET region. The vertical dielectric pillar extends downward through the BDI layer into the substrate. The vertical dielectric pillar further extends upward through the conductive gate material to a dielectric located above the gate region.

A quantum device is fabricated by forming a network of nanowires oriented in a plane of a substrate to produce a Majorana-based topological qubit. The nanowires are formed from combinations of selective-area-grown semiconductor material along with regions of a superconducting material. The selective-area-grown semiconductor material is grown by etching trenches to define the nanowires and depositing the semiconductor material in the trenches. A side gate is formed in an etched trench and situated to control a topological segment of the qubit.

A semiconductor device includes a plurality of tunnel diodes, each of which includes a first semiconductor region of a first conductive type and a second semiconductor region of a second conductive type that is provided above the first semiconductor region, the second semiconductor region being a nanowire shape; an insulating film provided around a side surface of the second semiconductor region; a plurality of first electrodes, each coupled to the first semiconductor region; and a plurality of second electrodes, each coupled to the second semiconductor region, wherein the second electrode has a first surface that faces the side surface of the second semiconductor region across the insulating film, and a diameter of a second semiconductor region of a first tunnel diode of the plurality of tunnel diodes is different from a diameter of a second semiconductor region of a second tunnel diode.

Aspects of the present disclosure provide a method of manufacturing a three-dimensional (3D) semiconductor device. For example, the method can include forming a target structure, the target structure including a lower gate region, an upper gate region, and a separation layer disposed between and separating the lower gate region and the upper gate region. The method can also include forming a sacrificial contact structure extending vertically from the bottom gate region through the separation layer and the upper gate region to a position above the upper gate region, removing at least a portion of the sacrificial contact structure resulting in a lower gate contact opening extending from the position above the upper gate region to the bottom gate region, insulating a side wall surface of the lower gate contact opening, and filling the lower gate contact opening with a conductor to form a lower gate contact.