A method includes forming a contact spacer on a sidewall of an inter-layer dielectric, wherein the contact spacer encircles a contact opening, forming a silicide region in the opening and on a source/drain region, depositing an adhesion layer extending into the contact opening, and performing a treatment process, so that the contact spacer is treated. The treatment process is selected from the group consisting of an oxidation process, a carbonation process, and combinations thereof. The method further includes depositing a metal barrier over the adhesion layer, depositing a metallic material to fill the contact opening, and performing a planarization process to remove excess portions of the metallic material over the inter-layer dielectric.

A method includes forming a first transistor in a first wafer, wherein the first transistor includes a first source/drain region, forming a first bond pad electrically coupling to the first source/drain region, forming an second transistor in a second wafer, wherein the second transistor includes a second source/drain region, forming a second bond pad electrically coupling to the second source/drain region, and bonding the second wafer to the first wafer, with the second bond pad being bonded to the first bond pad.

Embodiments of the present disclosure relates to a semiconductor device structure. The structure includes a first source/drain feature, a first interlayer dielectric (ILD) disposed over the first source/drain feature, a first conductive feature extending through the first ILD and in electrical contact with the first source/drain feature, and a gate electrode layer extending through the first ILD and disposed adjacent the first conductive feature, wherein a top surface of the first conductive feature and a top surface of the gate electrode layer are substantially co-planar.

A method for manufacturing a semiconductor device including an upper-channel implant transistor is provided. The method includes forming one or more fins extending in a first direction over a substrate. The one or more fins include a first region along the first direction and second regions on both sides of the first region along the first direction. A dopant is shallowly implanted in an upper portion of the first region of the fins but not in the second regions and not in a lower portion of the first region of the fins. A gate structure extending in a second direction perpendicular to the first direction is formed overlying the first region of the fins, and source/drains are formed overlying the second regions of the fins, thereby forming an upper-channel implant transistor.

Methods for improving profiles of channel regions in semiconductor devices and semiconductor devices formed by the same are disclosed. In an embodiment, a method includes forming a semiconductor fin over a semiconductor substrate, the semiconductor fin including germanium, a germanium concentration of a first portion of the semiconductor fin being greater than a germanium concentration of a second portion of the semiconductor fin, a first distance between the first portion and a major surface of the semiconductor substrate being less than a second distance between the second portion and the major surface of the semiconductor substrate; and trimming the semiconductor fin, the first portion of the semiconductor fin being trimmed at a greater rate than the second portion of the semiconductor fin.

A method includes forming a mask layer above a substrate. The substrate is patterned by using the mask layer as a mask to form a trench in the substrate. An isolation structure is formed in the trench, including feeding first precursors to the substrate. A bias is applied to the substrate after feeding the first precursors. With the bias turned on, second precursors are fed to the substrate. Feeding the first precursors, applying the bias, and feeding the second precursors are repeated.

Various embodiments of the present disclosure are directed towards a method for forming an integrated chip. The method includes forming an epitaxial structure having a first doping type over a first portion of a semiconductor substrate. A second portion of the semiconductor substrate is formed over the epitaxial structure and the first portion of the semiconductor substrate. A first doped region having the first doping type is formed in the second portion of the semiconductor substrate and directly over the epitaxial structure. A second doped region having a second doping type opposite the first doping type is formed in the second portion of the semiconductor substrate, where the second doped region is formed on a side of the epitaxial structure. A plurality of fins of the semiconductor substrate are formed by selectively removing portions of the second portion of the semiconductor substrate.

Non-planar semiconductor devices having doped sub-fin regions and methods of fabricating non-planar semiconductor devices having doped sub-fin regions are described. For example, a method of fabricating a semiconductor structure involves forming a plurality of semiconductor fins above a semiconductor substrate. A solid state dopant source layer is formed above the semiconductor substrate, conformal with the plurality of semiconductor fins. A dielectric layer is formed above the solid state dopant source layer. The dielectric layer and the solid state dopant source layer are recessed to approximately a same level below a top surface of the plurality of semiconductor fins, exposing protruding portions of each of the plurality of semiconductor fins above sub-fin regions of each of the plurality of semiconductor fins. The method also involves driving dopants from the solid state dopant source layer into the sub-fin regions of each of the plurality of semiconductor fins.

Non-planar I/O and logic semiconductor devices having different workfunctions on common substrates and methods of fabricating non-planar I/O and logic semiconductor devices having different workfunctions on common substrates are described. For example, a semiconductor structure includes a first semiconductor device disposed above a substrate. The first semiconductor device has a conductivity type and includes a gate electrode having a first workfunction. The semiconductor structure also includes a second semiconductor device disposed above the substrate. The second semiconductor device has the conductivity type and includes a gate electrode having a second, different, workfunction.

A method includes forming a fin extending from a substrate; depositing a liner over a top surface and sidewalls of the fin, where the minimum thickness of the liner is dependent on selected according to a first germanium concentration of the fin; forming a shallow trench isolation (STI) region adjacent the fin; removing a first portion of the liner on sidewalls of the fin, the first portion of the liner being above a topmost surface of the STI region; and forming a gate stack on sidewalls and a top surface of the fin, where the gate stack is in physical contact with the liner.