A method of producing a semiconductor device is disclosed in which, after proton implantation is performed, a hydrogen-induced donor is formed by a furnace annealing process to form an n-type field stop layer. A disorder generated in a proton passage region is reduced by a laser annealing process to form an n-type disorder reduction region. As such, the n-type field stop layer and the n-type disorder reduction region are formed by the proton implantation. Therefore, it is possible to provide a stable and inexpensive semiconductor device which has low conduction resistance and can improve electrical characteristics, such as a leakage current, and a method for producing the semiconductor device.

Zero expanded functional gate structures are formed by utilizing a dipole material spacer as a means to prevent expanded void formation during a replacement metal gate process. Notably, the dipole material spacer prevents expanded void formation into the dielectric spacer thus preventing the functional gate structures from being in direct physical contact with the source/drain regions. Improvement in yield loss and reliability is thus provided utilizing a dipole material spacer during a replacement metal gate process.

Patterning electronic devices using reactive-ion etching of tin oxides is provided. Reactive-ion etching facilitates patterning of tin oxides, such as barium stannate (BaSnO.sub.3), at a consistent and controllable etch rate. The reactive-ion etching approach described herein facilitates photolithographic patterning of tin oxide-based semiconductors to produce electronic devices, such as thin-film transistors (TFTs). This approach further patterns a tin oxide-based semiconductor without adversely affecting its electrical properties (e.g., resistivity, electron or hole mobility), as well as maintaining surface roughness. This approach can be used to produce optically transparent devices with high drain current (I.sub.D, drain-to-source current per channel width) and high on-off ratio.

Methods of cutting gate structures, and structures formed, are described. In an embodiment, a structure includes first and second gate structures over an active area, and a gate cut-fill structure. The first and second gate structures extend parallel. The active area includes a source/drain region disposed laterally between the first and second gate structures. The gate cut-fill structure has first and second primary portions and an intermediate portion. The first and second primary portions abut the first and second gate structures, respectively. The intermediate portion extends laterally between the first and second primary portions. First and second widths of the first and second primary portions along longitudinal midlines of the first and second gate structures, respectively, are each greater than a third width of the intermediate portion midway between the first and second gate structures and parallel to the longitudinal midline of the first gate structure.

Methods of cutting gate structures, and structures formed, are described. In an embodiment, a structure includes first and second gate structures over an active area, and a gate cut-fill structure. The first and second gate structures extend parallel. The active area includes a source/drain region disposed laterally between the first and second gate structures. The gate cut-fill structure has first and second primary portions and an intermediate portion. The first and second primary portions abut the first and second gate structures, respectively. The intermediate portion extends laterally between the first and second primary portions. First and second widths of the first and second primary portions along longitudinal midlines of the first and second gate structures, respectively, are each greater than a third width of the intermediate portion midway between the first and second gate structures and parallel to the longitudinal midline of the first gate structure.

Device scaling has increased the device density of integrated circuits (ICs) and reduced the cost of circuits. Today development of new device structures, use of new materials and complex process steps are implemented to continue scaling of the semiconductor devices. The added manufacturing steps and complexity have increased cost of ICs directly impacting the implementation of IoT devices that need low cost and high yields to be successful. ALEFT-M-LTSEE is a device that reduces cost while improving device performance by S/D resistance reduction. ALEFT-M-LTSEE enable scaling of gate and channel lengths while reducing impact of random threshold variation due to discrete dopants in and around the channel. By creating a flat field profile at the gate by use of low temperature epitaxy as source/drain extension, the short channel effects, and the impact of line edge variations of the gate are reduced.

A semiconductor device may include a substrate including first and second active regions and a field region therebetween, first and second active patterns respectively provided on the first and second active regions, first and second source/drain patterns respectively provided on the first and second active patterns, a first channel pattern between the first source/drain patterns and a second channel pattern between the second source/drain patterns, and a gate electrode extended from the first channel pattern to the second channel pattern to cross the field region. Each of the first and second channel patterns may include semiconductor patterns, which are stacked to be spaced apart from each other. A width of a lower portion of the gate electrode on the field region may decrease with decreasing distance from a top surface of the substrate.

Aspects of the disclosure provide a method for forming a fin field effect transistor (FinFET) incorporating a fin top hardmask on top of a channel region of a fin. Because of the presence of the fin top hardmask, a gate height of the FinFET can be reduced without affecting proper operations of vertical gate channels on sidewalls of the fin. Consequently, parasitic capacitance between a gate stack and source/drain contacts of the FinFET can be reduced by lowering the gate height of the FinFET.

A method for fabricating a semiconductor device includes receiving a finned substrate comprising an isolation layer with a plurality of semiconductor fins formed thereon, forming a gate structure over a fin that comprises a gate and a seed layer disposed below the gate and immediately adjacent to the fin, and epitaxially growing a gate extender from the seed layer that laterally extends over a source or drain region of the fin. In one embodiment, a semiconductor device includes a finned substrate comprising an isolation layer with a plurality of semiconductor fins formed thereon, a gate structure formed over a fin of the plurality of fins, the gate structure comprising a gate and a seed layer disposed below the gate and immediately adjacent to the fin, and a gate extender epitaxially grown from the seed layer that laterally extends over a source or drain region of the fin.

Integrated circuits having nickel silicide contacts and methods for fabricating integrated circuits with nickel silicide contacts are provided. An exemplary method for fabricating an integrated circuit includes providing a semiconductor substrate and forming a nonvolatile memory structure over the semiconductor substrate. The nonvolatile memory structure includes a gate surface. The method further includes depositing a nickel-containing material over the gate surface. Also, the method includes annealing the nonvolatile memory structure and forming a nickel silicide contact on the gate surface from the nickel-containing material.