A method includes forming a gate dielectric layer and a dummy gate layer; forming a mask over the dummy gate layer; patterning the gate dielectric layer and the dummy gate layer to form a dummy gate structure, the dummy gate structure including a remaining portion of the gate dielectric layer and a remaining portion of the dummy gate layer; epitaxially growing a first spacer layer on the dummy gate structure and the substrate, in which the first spacer layer has a higher growth rate on the exposed surfaces of the dummy gate structure and the substrate than on exposed surfaces of the mask; doping the first spacer layer to form a doped spacer layer having a different lattice constant than the substrate; depositing a second spacer layer over the doped spacer layer; and etching the second spacer layer and the doped spacer layer to form a gate spacer.

Some embodiments relate to a manufacturing method for a semiconductor device. In this method, a semiconductor workpiece, which includes a metal gate electrode thereon, is provided. An opening is formed in the semiconductor workpiece to expose a surface of the metal gate. Formation of the opening leaves a polymeric residue on the workpiece. To remove the polymeric residue from the workpiece, a cleaning solution that includes an organic alkali component is used. Other embodiments related to a semiconductor device resulting from the method.

A semiconductor structure includes an isolation feature formed in the semiconductor substrate and a first fin-type active region. The first fin-type active region extends in a first direction. A dummy gate stack is disposed on an end region of the first fin-type active region. The dummy gate stack may overlie an isolation structure. In an embodiment, any recess such as formed for a source/drain region in the first fin-type active region will be displaced from the isolation region by the distance the dummy gate stack overlaps the first fin-type active region.

Semiconductor devices, fin field effect transistor (FinFET) devices, and methods of manufacturing semiconductor devices are disclosed. In some embodiments, a semiconductor device includes a substrate comprising a first fin and a second fin. A first epitaxial fin is disposed over the first fin, and a second epitaxial fin is disposed over the second fin. The second fin is proximate the first fin. The first epitaxial fin and the second epitaxial fin have an upper portion with a substantially pillar shape.

A representative fin field effect transistor (FinFET) includes a substrate having a major surface; a fin structure protruding from the major surface having a lower portion comprising a first semiconductor material having a first lattice constant; an upper portion comprising the first semiconductor material. A bottom portion of the upper portion comprises a dopant with a first peak concentration. A middle portion is disposed between the lower portion and upper portion, where the middle portion comprises a second semiconductor material having a second lattice constant different from the first lattice constant. An isolation structure surrounds the fin structure, where a portion of the isolation structure adjacent to the bottom portion of the upper portion comprises the dopant with a second peak concentration equal to or greater than the first peak concentration.

An apparatus including a heterostructure disposed on a substrate and defining a channel region, the heterostructure including a first material having a first band gap less than a band gap of a material of the substrate and a second material having a second band gap that is greater than the first band gap; and a gate stack on the channel region, wherein the second material is disposed between the first material and the gate stack. A method including forming a first material having a first band gap on a substrate; forming a second material having a second band gap greater than the first band gap on the first material; and forming a gate stack on the second material.

Methods of forming a semiconductor structure include providing a multi-layer substrate having an epitaxial base layer overlying a strained primary semiconductor layer above a buried oxide layer. Elements within the epitaxial base layer are used to alter a strain state in the primary semiconductor layer within a first region of the multi-layer substrate without altering a strain state in the primary semiconductor layer within a second region of the multi-layer substrate. A first plurality of transistor channel structures are formed that each comprise a portion of the primary semiconductor layer within the first region of the multi-layer substrate, and a second plurality of transistor channel structures are formed that each comprise a portion of the primary semiconductor layer within the second region of the multi-layer substrate. Semiconductor structures fabricated by such methods may include transistor channel structures having differing strain states.

In one embodiment, a semiconductor device comprises one or more defense layers, the one or more defense layers each characterized by at least two lattice constants that are mismatched, wherein a mismatch in the lattice constants causes a destabilizing force that comprises at least one of a tensile force or a compressive force; and a plurality of other layers, wherein at least a sufficient part of the destabilizing force is restrained for the one or more defense layers to remain intact unless reduction in thickness of at least a section of one or more of the plurality of other layers, causes at least some of the destabilizing force that was restrained to no longer be restrained, and consequently at least part of at least one of the one or more defense layers to break.

A semiconductor structure includes an isolation feature formed in the semiconductor substrate and a first fin-type active region. The first fin-type active region extends in a first direction. A dummy gate stack is disposed on an end region of the first fin-type active region. The dummy gate stack may overlie an isolation structure. In an embodiment, any recess such as formed for a source/drain region in the first fin-type active region will be displaced from the isolation region by the distance the dummy gate stack overlaps the first fin-type active region.

A semiconductor device and a method for fabricating a semiconductor device involve a semiconductor layer that includes a first material and a second material. The first and second materials can be silicon and germanium. A contact of the device has a portion proximal to the semiconductor layer and a portion distal to the semiconductor layer. The distal portion includes the first material and the second material. A metal layer formed adjacent to the relaxed semiconductor layer and adjacent to the distal portion of the contact is simultaneously reacted with the relaxed semiconductor layer and with the distal portion of the contact to provide metallic contact material.