Abstract: A semiconductor device includes a semiconductor substrate comprising a contact region, a silicide present on the contact region, a dielectric layer present on the semiconductor substrate, the dielectric layer comprising an opening to expose a portion of the contact region, a conductor present in the opening, a barrier layer present between the conductor and the dielectric layer, and a metal layer present between the barrier layer and the dielectric layer, wherein a Si concentration of the silicide is varied along a height of the silicide.

Abstract: Contact structures and methods of forming contacts structures are contemplated by this disclosure. A structure includes a dielectric layer over a substrate, an adhesion layer, a silicide, a barrier layer, and a conductive material. The dielectric layer has an opening to a surface of the substrate. The adhesion layer is along sidewalls of the opening. The silicide is on the surface of the substrate. The barrier layer is on the adhesion layer and the silicide, and the barrier layer directly adjoins the silicide. The conductive material is on the barrier layer in the opening.

Abstract: Embodiments of the present disclosure include contact structures and methods of forming the same. An embodiment is a method of forming a semiconductor device, the method including forming a contact region over a substrate, forming a dielectric layer over the contact region and the substrate, and forming an opening through the dielectric layer to expose a portion of the contact region. The method further includes forming a metal-silicide layer on the exposed portion of the contact region and along sidewalls of the opening; and filling the opening with a conductive material to form a conductive plug in the dielectric layer, the conductive plug being electrically coupled to the contact region.

Abstract: A method of manufacturing a semiconductor structure including a conductive structure, a dielectric layer, and a plurality of conductive features is disclosed. The dielectric layer is formed on the conductive structure. A plurality of through holes is formed in the dielectric layer using a metal hard mask, and at least one of the through holes exposes the conductive structure. The conductive features are formed in the through holes. At least one of the conductive features has a bottom surface and at least one sidewall. The bottom surface and the sidewall of the conductive feature intersect to form an interior angle. The interior angles of adjacent two of the conductive features have a difference less than or substantially equal to about 3 degrees.

Abstract: A semiconductor device structure including a resistor layer is provided. The semiconductor device structure includes a gate structure formed over the first region of the substrate and an inter-layer dielectric (ILD) layer formed adjacent to the gate structure. The semiconductor device structure further includes a resistor layer is formed over the ILD layer over the second region of the substrate, and the major structure of the resistor layer is amorphous.

Abstract: An embodiment contact plug includes a bilayer structure and a diffusion barrier layer on a sidewall and a bottom surface of the bilayer structure. The bilayer structure includes a conductive core and a conductive liner on a sidewall and a bottom surface of the conductive core. In the embodiment contact plug, the conductive liner comprises cobalt or ruthenium.

Abstract: A semiconductor device includes a semiconductor substrate comprising a contact region, a silicide present on the contact region, a dielectric layer present on the semiconductor substrate, the dielectric layer comprising an opening to expose a portion of the contact region, a conductor present in the opening, a barrier layer present between the conductor and the dielectric layer, and a metal layer present between the barrier layer and the dielectric layer, wherein a Si concentration of the silicide is varied along a height of the silicide.

Abstract: A lighting device for a sheet metal is provided, for emitting lights on a sheet metal. The lighting device includes: a bottom plate; a wireless remote module, including a signal receiver for receiving a wireless control signal; a plurality of lighting modules, for emitting a plurality of light colors; a cover body, covering the lighting modules and including a light translucent portion and a light opaque portion. The wireless remote module controls the lighting modules to emit light. The light from the lighting modules goes through the light translucent portion and projects a projection boundary defined by a common boundary constructed by the light translucent portion and the light opaque portion on the sheet metal. A lighting system for a sheet metal is also provided, including the lighting device described above and a support device. The lighting device is adjustably assembled with the support device.

Abstract: A semiconductor device and method of formation are provided. The semiconductor device comprises a metal plug in a first opening over a substrate. The metal plug has a contact bottom surface that is substantially convex. The substantially convex contact bottom surface has an increased contact area as compared to a contact bottom surface of a metal plug that is not substantially convex. The increased contact area decreases a resistance of the metal plug. The increased contact area requires a smaller deposition amount to form a metal plug seed layer of the metal plug than a semiconductor device with a smaller contact area. A smaller deposition amount reduces an overhang of the deposited metal plug seed layer material. A reduced overhang of the deposited metal plug seed layer material reduces pitting in a metal plug formed from the deposited metal plug seed layer material.

Abstract: A semiconductor structure includes a conductive structure, a dielectric layer, and a plurality of conductive features. The dielectric layer is present on the conductive structure. The dielectric layer has a plurality of through holes therein, and at least one of the through holes exposes the conductive structure. The conductive features are respectively present in the through holes. At least one of the conductive features has a bottom surface and at least one sidewall. The bottom surface and the sidewall of the conductive feature intersect to form an interior angle. The interior angles of adjacent two of the conductive features have a difference less than or substantially equal to about 3 degrees.

Abstract: Embodiments of the present disclosure include contact structures and methods of forming the same. An embodiment is a method of forming a semiconductor device, the method including forming a contact region over a substrate, forming a dielectric layer over the contact region and the substrate, and forming an opening through the dielectric layer to expose a portion of the contact region. The method further includes forming a metal-silicide layer on the exposed portion of the contact region and along sidewalls of the opening; and filling the opening with a conductive material to form a conductive plug in the dielectric layer, the conductive plug being electrically coupled to the contact region.

Abstract: A semiconductor device includes a semiconductor substrate, an epitaxy structure present in the semiconductor substrate, and a silicide present on a textured surface of the epitaxy structure. A plurality of sputter ions are present between the silicide and the epitaxy structure. Since the surface of the epitaxy structure is textured, the contact area provided by the silicide is increased accordingly, thus the resistance of a interconnection structure in the semiconductor device is reduced.

Abstract: A semiconductor device and method of formation are provided. The semiconductor device comprises a metal plug in a first opening over a substrate, the metal plug is over a silicide layer, and the silicide layer is over a metal oxide layer. The metal oxide layer has an oxygen gradient, such that a percentage of oxygen increases from a top surface of the metal oxide layer to a bottom surface of the metal oxide layer. The metal oxide layer unpins the Fermi level of the interface between the metal plug and the substrate, which is exhibited by a lowered Schottky barrier height (SBH) and increased oxygen vacancy states between the V.B. and the C.B. of the metal oxide layer, which decreases the intrinsic resistivity between the metal plug and the substrate as compared to a semiconductor device that lacks such a metal oxide layer.

Abstract: A USB Type-C connector includes a transmission conductor group arranged according to functions and positions associated with electric characteristics. The transmission conductor group includes a first signal transmission conductor group, a second signal transmission conductor group, and a power transmission conductor group. Considering the way of arrangement, the second signal transmission conductor group is located at one side of the first signal transmission conductor group and the power transmission conductor group is similarly located at one side of the first signal transmission conductor group. As such, with such an arrangement, advantages of improved interference resistance, bettered performance of high frequency, and large electric current can be achieved.

Abstract: A semiconductor device includes a semiconductor substrate, a contact region present in the semiconductor substrate, and a silicide present on a textured surface of the contact region. A plurality of sputter ions are present between the silicide and the contact region. Since the surface of the contact region is textured, the contact area provided by the silicide is increased accordingly, thus the resistance of a interconnection structure in the semiconductor device is reduced.

Abstract: A semiconductor device includes a semiconductor substrate comprising a contact region, a silicide present on the contact region, a dielectric layer present on the semiconductor substrate, the dielectric layer comprising an opening to expose a portion of the contact region, a conductor present in the opening, a barrier layer present between the conductor and the dielectric layer, and a metal layer present between the barrier layer and the dielectric layer, wherein a Si concentration of the silicide is varied along a height of the silicide.

Abstract: An interconnect structure and a method of forming an interconnect structure are disclosed. The interconnect structure includes a contact layer over a substrate, a dielectric layer over the contact layer, a silicide layer over the exposed portion of the contact layer, a barrier layer along sidewalls of the opening, an alloy layer over the barrier layer, a glue layer over the alloy layer, and a conductive plug over the glue layer, wherein the dielectric layer has an opening, and the opening exposes a portion of the contact layer.

Abstract: A semiconductor device includes a semiconductor substrate, a contact region present in the semiconductor substrate, and a silicide present on a textured surface of the contact region. A plurality of sputter ions are present between the silicide and the contact region. Since the surface of the contact region is textured, the contact area provided by the silicide is increased accordingly, thus the resistance of a interconnection structure in the semiconductor device is reduced.

Abstract: A semiconductor device structure including a resistor layer is provided. The semiconductor device structure includes a gate structure formed over the first region of the substrate and an inter-layer dielectric (ILD) layer formed adjacent to the gate structure. The semiconductor device structure further includes a resistor layer is formed over the ILD layer over the second region of the substrate, and the major structure of the resistor layer is amorphous.

Abstract: Disclosed herein is a method of forming a metal-to-semiconductor contact with a doped metal oxide interlayer. An insulating layer is formed on a top surface of a semiconductor substrate with target region at the top surface of the semiconductor substrate. An opening is etched through the insulating layer with the opening exposing a top surface of a portion of the target region. A doped metal oxide interlayer is formed in the opening and contacts the top surface of the target region. The remainder of the opening is filled with a metal plug, the doped metal oxide interlayer disposed between the metal plug and the substrate. The doped metal oxide interlayer is formed from one of tin oxide, titanium oxide or zinc oxide and is doped with fluorine.