Abstract: A charging control circuit includes: a communications interface housing, a communications interface, and a control sub-circuit the communications interface housing includes a first conductive part, a second conductive part, and an insulating part, and the insulating part is disposed between the first conductive part and the second conductive part; the first conductive part is connected to a first voltage terminal; the second conductive part is connected to a second voltage terminal; a first voltage accessed at the first voltage terminal is greater than a second voltage accessed at the second voltage terminal; and when it is detected that a voltage of the first conductive part changes from the first voltage to the second voltage, starting of a power supply apparatus electrically connected to the communications interface, so that the power supply apparatus provides a charging voltage to the communications interface.

Abstract: A charging control circuit includes: a communications interface housing, a communications interface, and a control sub-circuit the communications interface housing includes a first conductive part, a second conductive part, and an insulating part, and the insulating part is disposed between the first conductive part and the second conductive part; the first conductive part is connected to a first voltage terminal; the second conductive part is connected to a second voltage terminal; a first voltage accessed at the first voltage terminal is greater than a second voltage accessed at the second voltage terminal; and when it is detected that a voltage of the first conductive part changes from the first voltage to the second voltage, starting of a power supply apparatus electrically connected to the communications interface, so that the power supply apparatus provides a charging voltage to the communications interface.

Abstract: Self-aligned contacts of a semiconductor device are fabricated by forming a metal gate structure on a portion of a semiconductor layer of a substrate. The metal gate structure contacts inner sidewalls of a gate spacer. A second sacrificial epitaxial layer is formed on a first sacrificial epitaxial layer. The first sacrificial epitaxial layer is adjacent to the gate spacer and is formed on source/drain regions of the semiconductor layer. The first and second sacrificial epitaxial layers are recessed. The recessing exposes at least a portion of the source/drain regions. A first dielectric layer is formed on the exposed portions of the source/drain regions, and over the gate spacer and metal gate structure. At least one cavity within the first dielectric layer is formed above at least one of the exposed portions of source/drain regions. At least one metal contact is formed within the at least one cavity.

Abstract: A semiconductor device comprises an insulation layer, an active semiconductor layer formed on an upper surface of the insulation layer, and a plurality of fins formed on the insulation layer. The fins are formed in the gate and spacer regions between a first source/drain region and second source/drain region, without extending into the first and second source/drain regions.

Abstract: A process for etching a bulk integrated circuit substrate to form features on the substrate, such as fins, having substantially vertical walls comprises forming an etch stop layer beneath the surface of the substrate by ion implantation, e.g., carbon, oxygen, or boron ions or combinations thereof, masking the surface with a patterned etching mask that defines the features by openings in the mask to produce a masked substrate and etching the masked substrate to a level of the etch stop layer to form the features. In silicon substrates, ion implantation takes place along a silicon crystalline lattice beneath the surface of the substrate. The etchant comprises a halogen material that etches undoped silicon faster than the implants-rich silicon layer. This produces a circuit where the fins do not taper away from the vertical where they meet the substrate, and corresponding products and articles of manufacture having these features.

Abstract: A method of forming a semiconductor device that includes forming a silicon including fin structure and forming a germanium including layer on the silicon including fin structure. Germanium is then diffused from the germanium including layer into the silicon including fin structure to convert the silicon including fin structure to silicon germanium including fin structure.

Abstract: A method of forming a semiconductor device that includes forming a silicon including fin structure and forming a germanium including layer on the silicon including fin structure. Germanium is then diffused from the germanium including layer into the silicon including fin structure to convert the silicon including fin structure to silicon germanium including fin structure.

Abstract: A semiconductor device, having a heterogeneous silicon stack, wherein the heterogeneous silicon stack comprises at least a base layer, a doped silicon layer, and an undoped silicon layer. The semiconductor device further includes a plurality of silicon fins atop a doped silicon oxide fin layer and an undoped silicon oxide fin layer, wherein the plurality of silicon fins have a uniform width along the height of the plurality of silicon fins, and wherein the plurality of silicon fins have a plurality of hard mask caps.

Abstract: A method for fabricating a self-aligned via structure includes forming a tri-layer mask on an ILD layer over a lower metal wiring layer, the tri-layer mask includes first and second insulating layers and a metal layer in between the insulating layers; defining a trench pattern through the first insulating layer and metal layer, the trench pattern having a first width; defining a first via pattern in a lithographic mask over the trench pattern, the first via pattern having a second width that is larger than the first width; growing a metal capping layer on an exposed sidewall of the trench pattern to decrease the first width to a third width that defines a second via pattern; transferring the trench pattern into the ILD layer to form a trench; and transferring the second via pattern through the ILD layer and into the metal wiring layer to form a via.

Abstract: Methods and structures for fabricating fins for multigate devices are disclosed. In accordance with one method, a plurality of sidewalls are formed in or on a plurality of mandrels over a semiconductor substrate such that each of the mandrels includes a first sidewall composed of a first material and a second sidewall composed of a second material that is different from the first material. The first sidewall of a first mandrel of the plurality of mandrels is selectively removed. In addition, a pattern composed of remaining sidewalls of the plurality of sidewalls is transferred onto an underlying layer to form a hard mask in the underlying layer. Further, the fins are formed by employing the hard mask and etching semiconducting material in the substrate.

Abstract: A method of forming a semiconductor device that includes forming a sacrificial gate structure on a channel portion of a fin structure, wherein the angle at the intersection of the sidewall of the sacrificial gate structure and an upper surface of the channel portion of the fin structure is obtuse. Epitaxial source and drain region structures are formed on a source region portion and a drain region portion of the fin structure. At least one dielectric material is formed on the sidewall of the sacrificial gate structure. The sacrificial gate structure may be removed to provide an opening to the channel portion of the fin structure. A function gate structure is formed in the opening. At least one angle defined by the intersection of a sidewall of the functional gate structure and an upper surface of the channel portion of the fin structure is obtuse.

Abstract: A method of forming a semiconductor device that includes forming a sacrificial gate structure on a channel portion of a fin structure, wherein the angle at the intersection of the sidewall of the sacrificial gate structure and an upper surface of the channel portion of the fin structure is obtuse. Epitaxial source and drain region structures are formed on a source region portion and a drain region portion of the fin structure. At least one dielectric material is formed on the sidewall of the sacrificial gate structure. The sacrificial gate structure may be removed to provide an opening to the channel portion of the fin structure. A function gate structure is formed in the opening. At least one angle defined by the intersection of a sidewall of the functional gate structure and an upper surface of the channel portion of the fin structure is obtuse.

Abstract: A method of forming a semiconductor device that includes forming a silicon including fin structure and forming a germanium including layer on the silicon including fin structure. Germanium is then diffused from the germanium including layer into the silicon including fin structure to convert the silicon including fin structure to silicon germanium including fin structure.

Abstract: Self-aligned contacts of a semiconductor device are fabricated by forming a metal gate structure on a portion of a semiconductor layer of a substrate. The metal gate structure contacts inner sidewalls of a gate spacer. A second sacrificial epitaxial layer is formed on a first sacrificial epitaxial layer. The first sacrificial epitaxial layer is adjacent to the gate spacer and is formed on source/drain regions of the semiconductor layer. The first and second sacrificial epitaxial layers are recessed. The recessing exposes at least a portion of the source/drain regions. A first dielectric layer is formed on the exposed portions of the source/drain regions, and over the gate spacer and metal gate structure. At least one cavity within the first dielectric layer is formed above at least one of the exposed portions of source/drain regions. At least one metal contact is formed within the at least one cavity.

Abstract: A method for fabricating a self-aligned via structure includes forming a tri-layer mask on an ILD layer over a lower metal wiring layer, the tri-layer mask includes first and second insulating layers and a metal layer in between the insulating layers; defining a trench pattern through the first insulating layer and metal layer, the trench pattern having a first width; defining a first via pattern in a lithographic mask over the trench pattern, the first via pattern having a second width that is larger than the first width; growing a metal capping layer on an exposed sidewall of the trench pattern to decrease the first width to a third width that defines a second via pattern; transferring the trench pattern into the ILD layer to form a trench; and transferring the second via pattern through the ILD layer and into the metal wiring layer to form a via.

Abstract: Self-aligned contacts of a semiconductor device are fabricated by forming a metal gate structure on a portion of a semiconductor layer of a substrate. The metal gate structure contacts inner sidewalls of a gate spacer. A second sacrificial epitaxial layer is formed on a first sacrificial epitaxial layer. The first sacrificial epitaxial layer is adjacent to the gate spacer and is formed on source/drain regions of the semiconductor layer. The first and second sacrificial epitaxial layers are recessed. The recessing exposes at least a portion of the source/drain regions. A first dielectric layer is formed on the exposed portions of the source/drain regions, and over the gate spacer and metal gate structure. At least one cavity within the first dielectric layer is formed above at least one of the exposed portions of source/drain regions. At least one metal contact is formed within the at least one cavity.

Abstract: A semiconductor device comprises an insulation layer, an active semiconductor layer formed on an upper surface of the insulation layer, and a plurality of fins formed on the insulation layer. The fins are formed in the gate and spacer regions between a first source/drain region and second source/drain region, without extending into the first and second source/drain regions.

Abstract: Methods for forming semiconductor devices having non-merged fin extensions. Methods for forming semiconductor devices include forming trenches in an insulator layer of a substrate. Fins are formed in the trenches and a dummy gate is formed over the fins, leaving a source and drain region exposed. The fins are etched below a surface level of a surrounding insulator layer. Fin extensions are epitaxially grown from the etched fins.

Abstract: A metal layer is deposited over an underlying material layer. The metal layer includes an elemental metal that can be converted into a dielectric metal-containing compound by plasma oxidation and/or nitridation. A hard mask portion is formed over the metal layer. Plasma oxidation or nitridation is performed to convert physically exposed surfaces of the metal layer into the dielectric metal-containing compound. The sequence of a surface pull back of the hard mask portion, trench etching, another surface pull back, and conversion of top surfaces into the dielectric metal-containing compound are repeated to form a line pattern having a spacing that is not limited by lithographic minimum dimensions.

Abstract: Semiconductor devices include multiple fins formed in trenches in an insulator layer. Each of the plurality of fins has a uniform crystal orientation and a fin cap in a source and drain region that extends vertically and laterally beyond the trench. The fin caps of the respective fins are separate from one another. A gate structure is formed over the fins that leaves the source and drain regions exposed. The insulator layer at least partially covers a sidewall of the gate structure.