An approach to forming a semiconductor structure with improved negative bias temperature instability includes diffusing fluorine atoms into a semiconductor structure by an anneal in a fluorine containing gas. The approach includes removing a pFET work function metal layer from an area above an nFET wherein the area above the nFET includes at least the area over the nFET. Additionally, the approach includes depositing a layer of nFET work function metal on a remaining portion of the pFET work function metal and depositing a gate metal over the nFET work function metal layer. Furthermore, the method includes performing an anneal in a reducing environment followed by a high temperature anneal.

An integrated circuit containing PMOS transistors may be formed by forming a dual layer hard mask. A first layer of the hard mask is halogen-containing silicon nitride formed using a halogenated silane reagent. A second layer of the hard mask is silicon nitride formed on the first layer using halogen-free reagents. After source/drain cavities are etched in the PMOS transistors, a pre-epitaxial bake with hydrogen is performed. After SiGe epitaxial source/drain regions are formed, the hard mask is removed.

A method of semiconductor device fabrication includes providing a fin extending from a substrate and having a source/drain region and a channel region. The fin includes a first layer, a second layer over the first layer, and a third layer over the second layer. A gap is formed by removing at least a portion of the second layer from the channel region. A first material is formed in the channel region to form first and second interfacial layer portions, each at least partially wrapping around the first and third layers respectively. A second material is deposited in the channel region to form first and second high-k dielectric layer portions, each at least partially wrapping around the first and second interfacial layer portions. A metal layer including a scavenging material is formed along opposing sidewalls of the first and second high-k dielectric layer portions in the channel region.

A semiconductor includes a first transistor and a second transistor. The first transistor includes a first and a second epitaxial layer, formed of a first semiconductor material. The second epitaxial layer is disposed over the first epitaxial layer. The first transistor also includes a first gate dielectric layer surrounds the first and second epitaxial layers and extends from a top surface of the first epitaxial layer to a bottom surface of the second epitaxial layer and a first metal gate layer surrounding the first gate dielectric layer. The second transistor includes a third epitaxial layer formed of the first semiconductor material and a fourth epitaxial layer disposed directly on the third epitaxial layer and formed of a second semiconductor. The second transistor also includes a second gate dielectric layer disposed over the third and fourth epitaxial layers and a second metal gate layer disposed over the second gate dielectric layer.

A device includes a vertical transistor comprising a first buried layer over a substrate, a first well over the first buried layer, a first gate in a first trench, wherein the first trench is formed partially through the first buried layer, and wherein a dielectric layer and the first gate are in the first trench, a second gate in a second trench, wherein the second trench is formed partially through the first buried layer, and wherein the second trench is of a same depth as the first trench, a first drain/source region and a second drain/source region formed on opposite sides of the first trench and a first lateral transistor comprising a second buried layer formed over the substrate, a second well over the second buried layer and drain/source regions over the second well.

An integrated circuit and method with dual stress liners and with NMOS transistors with gate overhang of active that is longer than the minimum design rule and with PMOS transistors with gate overhang of active that are not longer than the minimum design rule.

A semiconductor device may include a first gate electrode being formed on a substrate and having a first ratio of a width of an upper surface to a width of a lower surface, a second gate electrode being formed on the substrate and having a second ratio of the width of the upper surface to the width of the lower surface, wherein the second ratio is less than the first ratio, a first gate spacer being formed on a sidewall of the first gate electrode, a second gate spacer being formed on a sidewall of the second gate electrode and an interlayer insulating film covering the first gate spacer and the second gate spacer.

A fin field effect transistor (FinFET) having a tunable tensile strain and an embodiment method of tuning tensile strain in an integrated circuit are provided. The method includes forming a source/drain region on opposing sides of a gate region in a fin, forming spacers over the fin, the spacers adjacent to the source/drain regions, depositing a dielectric between the spacers; and performing an annealing process to contract the dielectric, the dielectric contraction deforming the spacers, the spacer deformation enlarging the gate region in the fin.

A semiconductor device includes an interlayer insulating film formed on a substrate and including a trench, a gate insulating film formed in the trench, a work function adjusting film formed on the gate insulating film in the trench along sidewalls and a bottom surface of the trench, and including an inclined surface having an acute angle with respect to the sidewalls of the trench, and a metal gate pattern formed on the work function adjusting film in the trench to fill up the trench.

A semiconductor arrangement includes a first semiconductor device including a first type region having a first conductivity type and a second type region having a second conductivity type. The semiconductor arrangement includes a second semiconductor device adjacent the first semiconductor device. The second semiconductor device includes a third type region having a third conductivity type and a fourth type region having a fourth conductivity type. The semiconductor arrangement includes a first insulator layer including a first insulator portion around at least some of the first semiconductor device and a second insulator portion around at least some of the second semiconductor device. The first insulator portion has a first insulator height, and the second insulator portion has a second insulator height. The first insulator height is different than the second insulator height. A method of forming a semiconductor arrangement is provided.