A semiconductor device includes a substrate, a first active fin, a second active fin, a dummy fin and a first gate structure. The first and the second active fin are on the substrate and extend along a first direction. The dummy fin is disposed between the first active fin and the second active fin, and extends in the first direction. The dummy fin includes a plurality of layers, and each of the layers includes a material different from another layer. The first gate structure crosses over the dummy fin, the first and the second active fins.

A semiconductor structure is provided that includes a plurality of high mobility semiconductor material (i.e., silicon germanium alloy of III-V compound semiconductors) fins located above and spaced apart from a bulk semiconductor substrate portion, wherein each of the high mobility semiconductor material fins has a lower faceted surface that is confined within a dielectric isolation structure.

A laser structure may include a substrate, an active region arranged on the substrate, and a waveguide arranged on the active region. The waveguide may include a first surface and a second surface that join to form a first angle relative to the active region. A material may be deposited on the first surface and the second surface of the waveguide.

A method includes forming a dielectric layer over a carrier, forming a plurality of bond pads in the dielectric layer, and performing a planarization to level top surfaces of the dielectric layer and the plurality of bond pads with each other. A device die is bonded to the dielectric layer and portions of the plurality of bond pads through hybrid bonding. The device die is encapsulated in an encapsulating material. The carrier is then demounted from the device die and the dielectric layer.

Embodiments of methods for forming a hybrid-bonded semiconductor structure are disclosed. The method include disposing first second, third, and fourth dielectric layers, forming first and second openings by etching the fourth dielectric layer using a first etching selectivity, etching the third and fourth dielectric layers in the first and second openings respectively using a second etching selectivity, etching the second and third dielectric layers in the first and second openings using the first etching selectivity, etching the first dielectric layer in the first opening and the second dielectric layer in the second opening using the second etching selectivity, etching the first dielectric layer in the first and second openings using the first etching selectivity, and forming conductive material in the first and second openings.

A dielectric material layer is deposited on gate structures of first and second semiconductor material portions. The dielectric material layer is anisotropically etched to form a first gate spacer on a first semiconductor material portion, while being protected above the second semiconductor material portion. After formation of first raised active regions on the first semiconductor material portion, a dielectric stack of a dielectric oxide liner and a dielectric nitride liner is formed. The dielectric stack is removed over the second semiconductor material portion and a second gate spacer is formed on the second semiconductor material portion, while the dielectric stack protects the first raised active regions. A second gate spacer is formed by anisotropically etching the dielectric material layer over the second semiconductor material portion. The first and second gate spacers have the same composition and thickness. Second raised active regions can be formed on the second semiconductor material portion.

A method for patterning a metal layer includes depositing a hard mask layer on a metal layer, depositing a first patterned layer on the hard mask layer, forming a first set of sidewall spacers on sidewalls of features of the first patterned layer, forming a second set of sidewall spacers on sidewalls of the first set of sidewall spacers, removing the first set of sidewall spacers, and performing a reactive ion etching process to pattern portions of the metal layer exposed through the first patterned layer and the second set of sidewall spacers.

A method includes providing a structure having a first hardmask layer, interposer layer, second hardmask layer and mandrel layer disposed respectively over a dielectric stack. An array of mandrels is patterned into the mandrel layer with a mandrel mask. An ANA trench is patterned into the mandrel layer with a first cut mask. The ANA trench is patterned into the interposer layer with a second cut mask. An organic planarization layer (OPL) is disposed over the structure. The OPL is etched to dispose it only in the ANA trench such that a top surface of the OPL is lower than the second hardmask layer. The structure is etched to form a pattern in a dielectric layer of the dielectric stack to form an array of metal lines in the dielectric layer, a portion of the pattern formed by the ANA trench forms an ANA region within the dielectric layer.

In a substrate processing method according to the embodiment, a first material is implanted into a surface of a target film to modify the surface of the target film. The surface of the target film is dissolved to remove the surface of the target film by bringing a catalytic material close to the surface of the target film or by contacting the catalytic material to the surface of the target film while supplying a process solution on the surface of the target film which has been modified.

Disclosed are methods of growing III-V epitaxial layers on a substrate, semiconductor structures thus obtained, and devices comprising such semiconductor structures. An example semiconductor substrate includes a substrate and a buffer layer on top of the substrate, where a conductive path is present between the substrate and buffer layer. A conductive path may be present in the conductive interface, and the conductive path may be interrupted by one or more local electrical isolations. The local electrical isolation(s) may be positioned with the device such that at least one of the local electrical isolation(s) is located between a high voltage terminal and a low voltage terminal of the device.