Abstract: A method for fabricating a multiple gate width structure for an integrated circuit is described. A fin on a semiconductor substrate with a first hard mask layer is covered by a first and second sacrificial gate each of which includes a second hard mask layer. Spacer layers and a dielectric layer are formed over the first and second sacrificial gate structures. The resulting structure is planarized so that the first and second sacrificial gate structures and the dielectric layer have coplanar top surfaces. The first and second sacrificial gate structures are removed to respectively form first and second trench recesses in the dielectric layer. The trench recesses are filled with a conductor to form permanent gate structures. A first permanent gate structure is formed in the first trench recess has a first length and a second permanent gate structure is formed in the second trench recess has a second length greater than the first length.

Abstract: Process of using a dummy gate as an interconnection and a method of manufacturing the same are disclosed. Embodiments include forming on a semiconductor substrate dummy gate structures at cell boundaries, each dummy gate structure including a set of sidewall spacers and a cap disposed between the sidewall spacers; removing a first sidewall spacer or at least a portion of a first cap on a first side of a first dummy gate structure and forming a first gate contact trench over the first dummy gate structure; and filling the first gate contact trench with a metal to form a first gate contact.

Abstract: Semiconductor devices and methods of fabricating the semiconductor devices with chamfer-less via multi-patterning are disclosed. One method includes, for instance: obtaining an intermediate semiconductor device; performing a trench etch into a portion of the intermediate semiconductor device to form a trench pattern; depositing an etching stack; performing at least one via patterning process; and forming at least one via opening into a portion of the intermediate semiconductor device. An intermediate semiconductor device is also disclosed.

Abstract: Semiconductor devices and methods of fabricating the semiconductor devices with chamfer-less via multi-patterning are disclosed. One method includes, for instance: obtaining an intermediate semiconductor device; performing a trench etch into a portion of the intermediate semiconductor device to form a trench pattern; depositing an etching stack; performing at least one via patterning process; and forming at least one via opening into a portion of the intermediate semiconductor device. An intermediate semiconductor device is also disclosed.

Abstract: After semiconductor material portions and gate structures are formed on a substrate, a dielectric material layer is deposited on the semiconductor material portions and the gate structures. An anisotropic etch is performed on the dielectric material layer to form gate spacers, while a mask layer protects peripheral portions of the semiconductor material portions and the gate structures to avoid unwanted physical exposure of semiconductor surfaces. A selective epitaxy can be performed to form raised active regions on the semiconductor material portions. Formation of semiconductor growth defects during the selective epitaxy is prevented by the dielectric material layer. Alternately, a selective semiconductor deposition process can be performed after formation of dielectric gate spacers on gate structures overlying semiconductor material portions. Semiconductor growth defects can be removed by an etch while a mask layer protects raised active regions on the semiconductor material portions.

Abstract: Process of using a dummy gate as an interconnection and a method of manufacturing the same are disclosed. Embodiments include forming on a semiconductor substrate dummy gate structures at cell boundaries, each dummy gate structure including a set of sidewall spacers and a cap disposed between the sidewall spacers; removing a first sidewall spacer or at least a portion of a first cap on a first side of a first dummy gate structure and forming a first gate contact trench over the first dummy gate structure; and filling the first gate contact trench with a metal to form a first gate contact.

Abstract: A method of fabricating a semiconductor device includes forming at least one semiconductor fin on a semiconductor substrate. A plurality of gate formation layers is formed on an etch stop layer disposed on the fin. The plurality of gate formation layers include a dummy gate layer formed from a dielectric material. The plurality of gate formation layers is patterned to form a plurality of dummy gate elements on the etch stop layer. Each dummy gate element is formed from the dielectric material. A spacer layer formed on the dummy gate elements is etched to form a spacer on each sidewall of dummy gate elements. A portion of the etch stop layer located between each dummy gate element is etched to expose a portion the semiconductor fin. A semiconductor material is epitaxially grown from the exposed portion of the semiconductor fin to form source/drain regions.

Abstract: An aspect of the invention includes a freestanding spacer having a sub-lithographic dimension for a sidewall image transfer process. The freestanding spacer comprises: a first spacer layer having a first portion disposed on the semiconductor layer; and a second spacer layer having a first surface disposed on the first portion of the first spacer layer, wherein the first spacer layer has a first dielectric constant and the second spacer layer has a second dielectric constant, the first dielectric constant being greater than the second dielectric constant, and wherein a dimension of each of the first and second spacer layers collectively determine the sub-lithographic lateral dimension of the freestanding spacer.

Abstract: After semiconductor material portions and gate structures are formed on a substrate, a dielectric material layer is deposited on the semiconductor material portions and the gate structures. An anisotropic etch is performed on the dielectric material layer to form gate spacers, while a mask layer protects peripheral portions of the semiconductor material portions and the gate structures to avoid unwanted physical exposure of semiconductor surfaces. A selective epitaxy can be performed to form raised active regions on the semiconductor material portions. Formation of semiconductor growth defects during the selective epitaxy is prevented by the dielectric material layer. Alternately, a selective semiconductor deposition process can be performed after formation of dielectric gate spacers on gate structures overlying semiconductor material portions. Semiconductor growth defects can be removed by an etch while a mask layer protects raised active regions on the semiconductor material portions.

Abstract: Process of using a dummy gate as an interconnection and a method of manufacturing the same are disclosed. Embodiments include forming on a semiconductor substrate dummy gate structures at cell boundaries, each dummy gate structure including a set of sidewall spacers and a cap disposed between the sidewall spacers; removing a first sidewall spacer or at least a portion of a first cap on a first side of a first dummy gate structure and forming a first gate contact trench over the first dummy gate structure; and filling the first gate contact trench with a metal to form a first gate contact.

Abstract: An aspect of the invention includes a freestanding spacer having a sub-lithographic dimension for a sidewall image transfer process. The freestanding spacer comprises: a first spacer layer having a first portion disposed on the semiconductor layer; and a second spacer layer having a first surface disposed on the first portion of the first spacer layer, wherein the first spacer layer has a first dielectric constant and the second spacer layer has a second dielectric constant, the first dielectric constant being greater than the second dielectric constant, and wherein a dimension of each of the first and second spacer layers collectively determine the sub-lithographic lateral dimension of the freestanding spacer.

Abstract: Process of using a dummy gate as an interconnection and a method of manufacturing the same are disclosed. Embodiments include forming on a semiconductor substrate dummy gate structures at cell boundaries, each dummy gate structure including a set of sidewall spacers and a cap disposed between the sidewall spacers; removing a first sidewall spacer or at least a portion of a first cap on a first side of a first dummy gate structure and forming a first gate contact trench over the first dummy gate structure; and filling the first gate contact trench with a metal to form a first gate contact.

Abstract: Lithography stack, intermediate semiconductor devices, and methods of fabrication are provided. The method includes obtaining an intermediate semiconductor device with a substrate, applying a spin on carbon layer over the substrate, and applying a hardmask layer over the spin on carbon layer. The intermediate semiconductor device includes a substrate, a spin on carbon layer over the substrate, and a hardmask layer over the spin on carbon layer. The lithography stack includes a spin on carbon layer, an invisible hardmask layer over the spin on carbon layer, and a photoresist layer over the invisible hardmask layer.

Abstract: After semiconductor material portions and gate structures are formed on a substrate, a dielectric material layer is deposited on the semiconductor material portions and the gate structures. An anisotropic etch is performed on the dielectric material layer to form gate spacers, while a mask layer protects peripheral portions of the semiconductor material portions and the gate structures to avoid unwanted physical exposure of semiconductor surfaces. A selective epitaxy can be performed to form raised active regions on the semiconductor material portions. Formation of semiconductor growth defects during the selective epitaxy is prevented by the dielectric material layer. Alternately, a selective semiconductor deposition process can be performed after formation of dielectric gate spacers on gate structures overlying semiconductor material portions. Semiconductor growth defects can be removed by an etch while a mask layer protects raised active regions on the semiconductor material portions.

Abstract: A method includes forming a layer of material above a semiconductor substrate and performing a first sidewall image transfer process to form a first plurality of spacers and a second plurality of spacers above the layer of material, wherein the first and second pluralities of spacers are positioned above respective first and second regions of the semiconductor substrate and have a same initial width and a same pitch spacing. A masking layer is formed above the layer of material so as to cover the first plurality of spacers and expose the second plurality of spacers, and a first etching process is performed through the masking layer on the exposed second plurality of spacers so as to form a plurality of reduced-width spacers having a width that is less than the initial width, wherein the first plurality of spacers and the plurality of reduced-width spacers define an etch mask.

Abstract: Methods of forming features having differing pitch spacing and critical dimensions are disclosed herein. One method includes forming an underlying layer of material above a semiconductor substrate. The method further includes forming a masking layer above the underlying layer of material. The masking layer includes features positioned above a first region of the substrate and features positioned above a second region of the substrate. The features have different pitch spacing and critical dimensions. The method further includes performing at least one etching process on the underlying layer of material through the masking layer.

Abstract: Methods of forming integrated circuits and multiple CD SADP processes are provided that include providing a patternable structure including a first hard mask layer and a first patternable layer underlying the first hard mask layer. Mandrels are provided over the first hard mask layer. Sidewall spacers are formed adjacent sidewalls of the mandrels. The mandrels are removed, with the sidewall spacers remaining and defining gaps therebetween. The first hard mask layer is etched through the gaps to form a first patterned hard mask feature and a second patterned hard mask feature. A critical dimension of the first patterned hard mask feature is selectively modified to form a biased hard mask feature. A space is defined between sidewalls of the biased hard mask feature and the second patterned hard mask feature. The first patternable layer is etched through exposed material in the space.

Abstract: A method of fabricating a semiconductor device includes forming at least one semiconductor fin on a semiconductor substrate. A plurality of gate formation layers is formed on an etch stop layer disposed on the fin. The plurality of gate formation layers include a dummy gate layer formed from a dielectric material. The plurality of gate formation layers is patterned to form a plurality of dummy gate elements on the etch stop layer. Each dummy gate element is formed from the dielectric material. A spacer layer formed on the dummy gate elements is etched to form a spacer on each sidewall of dummy gate elements. A portion of the etch stop layer located between each dummy gate element is etched to expose a portion the semiconductor fin. A semiconductor material is epitaxially grown from the exposed portion of the semiconductor fin to form source/drain regions.

Abstract: Methods of forming features having differing pitch spacing and critical dimensions are disclosed herein. One method includes forming an underlying layer of material above a semiconductor substrate. The method further includes forming a masking layer above the underlying layer of material. The masking layer includes features positioned above a first region of the substrate and features positioned above a second region of the substrate. The features have different pitch spacing and critical dimensions. The method further includes performing at least one etching process on the underlying layer of material through the masking layer.

Abstract: A method includes forming a layer of material above a semiconductor substrate and performing a first sidewall image transfer process to form a first plurality of spacers and a second plurality of spacers above the layer of material, wherein the first and second pluralities of spacers are positioned above respective first and second regions of the semiconductor substrate and have a same initial width and a same pitch spacing. A masking layer is formed above the layer of material so as to cover the first plurality of spacers and expose the second plurality of spacers, and a first etching process is performed through the masking layer on the exposed second plurality of spacers so as to form a plurality of reduced-width spacers having a width that is less than the initial width, wherein the first plurality of spacers and the plurality of reduced-width spacers define an etch mask.