Abstract: An etch layer underlying a patterned photoresist mask is provided. A plurality of sidewall forming processes are performed. Each sidewall forming process comprises depositing a protective layer on the patterned photoresist mask by performing multiple cyclical depositions. Each cyclical deposition involves at least a depositing phase for depositing a deposition layer over surfaces of the patterned photoresist mask and a profile shaping phase for shaping vertical surfaces in the deposition layer. Each sidewall forming process further comprises a breakthrough etch for selectively etching horizontal surfaces of the protective layer with respect to vertical surfaces of the protective layer. Afterwards, the etch layer is etched to form a feature having a critical dimension that is less than the critical dimension of the features in the patterned photoresist mask.

Abstract: A method for forming fin structures is provided. Sacrificial structures are provided on a substrate. Fin structures are formed on the sides of the sacrificial structures. The forming of the fin structures comprises a plurality of cycles, wherein each cycle comprises a fin deposition phase and a fin profile shaping phase. The sacrificial structure is removed.

Abstract: A feature in a layer is provided. A photoresist layer is formed over the layer. The photoresist layer is patterned to form photoresist features with photoresist sidewalls, where the photoresist features have a first critical dimension. A conformal layer is deposited over the sidewalls of the photoresist features to reduce the critical dimensions of the photoresist features. Features are etched into the layer, wherein the layer features have a second critical dimension, which is less than the first critical dimension.

Abstract: A method for providing features in an etch layer is provided. A sacrificial patterned layer with sacrificial features is provided over an etch layer. Conformal sidewalls are formed in the sacrificial features, comprising at least two cycles of a sidewall formation process, wherein each cycle comprises a sidewall deposition phase and a sidewall profile shaping phase. Parts of the sacrificial patterned layer between conformal sidewalls are removed leaving the conformal sidewalls with gaps between the conformal sidewalls where parts of the sacrificial patterned layer were selectively removed. Features are etched in the etch layer using the conformal sidewalls as an etch mask, wherein the features in the etch layer are etched through the gaps between the conformal sidewalls where parts of the sacrificial patterned layer were selectively removed.

Abstract: A method of forming features in an etch layer disposed below a mask with features is provided. The mask is conditioned. The conditioning, comprising providing a conditioning gas consisting essentially of at least one noble gas, forming a plasma from the conditioning gas, and exposing the mask to the plasma from the conditioning gas. The features of the mask are shrunk. Features are etched into the etch layer through the shrunk features of the mask.

Abstract: A method for forming fin structures is provided. Sacrificial structures are provided on a substrate. Fin structures are formed on the sides of the sacrificial structures. The forming of the fin structures comprises a plurality of cycles, wherein each cycle comprises a fin deposition phase and a fin profile shaping phase. The sacrificial structure is removed.

Abstract: A method for reducing capacitances between semiconductor devices is provided. A plurality of contact structures is formed in a dielectric layer. A mask is formed to cover the contact structures wherein the mask has mask features for exposing parts of the dielectric layer wherein the mask features have widths. The widths of the mask features are shrunk with a sidewall deposition. Gaps are etched into the dielectric layer through the sidewall deposition. The gaps are closed to form pockets in the gaps.

Abstract: A method providing features in a dielectric layer is provided. A sacrificial layer is formed over the dielectric layer. A set of sacrificial layer features is etched into the sacrificial layer. A first set of dielectric layer features is etched into the dielectric layer through the sacrificial layer. The first set of dielectric layer features and the set of sacrificial layer features are filled with a filler material. The sacrificial layer is removed. The widths of the spaces between the parts of the filler material are shrunk with a shrink sidewall deposition. A second set of dielectric layer features is etched into the dielectric layer through the shrink sidewall deposition. The filler material and shrink sidewall deposition are removed.

Abstract: A method for etching features in an etch layer is provided. A patterned photoresist mask is formed over the etch layer with photoresist features with sidewalls wherein the sidewalls of the photoresist features have irregular profiles along depths of the photoresist features. The irregular profiles along the depths of the photoresist features of the sidewalls of the photoresist features are corrected comprising at least one cycle, where each cycle comprises a sidewall deposition phase and a profile shaping phase. Feature is etched into the etch layer through the photoresist features. The mask is removed.

Abstract: A plasma chamber with a plasma confinement zone with an electrode is provided. A gas distribution system for providing a first gas and a second gas is connected to the plasma chamber, wherein the gas distribution system can substantially replace one gas in the plasma zone with the other gas within a period of less than 1 s. A first frequency tuned RF power source for providing power to the electrode in a first frequency range is electrically connected to the at least one electrode wherein the first frequency tuned RF power source is able to minimize a reflected RF power. A second frequency tuned RF power source for providing power to the plasma chamber in a second frequency range outside of the first frequency range wherein the second frequency tuned RF power source is able to minimize a reflected RF power.

Abstract: A method for forming a feature in a layer with reduced line edge roughening is provided. A photoresist layer is formed over the layer. The photoresist layer is patterned to form photoresist features with photoresist sidewalls. A sidewall layer with a thickness less than 100 nm is formed over the sidewalls of the photoresist features by performing for a plurality of cycles. Each cycle comprises depositing a layer on the photoresist layer wherein the deposited layer has a thickness between a monolayer to 20 nm. Features are etched into the layer through the photoresist features. The photoresist layer and sidewall layer are stripped.

Abstract: A method for forming etch features in an etch layer over a substrate is provided. An etch mask stack is formed over the etch layer. A first mask is formed over the etch mask stack. A sidewall layer is formed over the first mask, which reduces the widths of the spaces defined by the first mask. A first set of features is etched into the etch mask stack through the sidewall layer. The mask and sidewall layer are removed. An additional feature step is performed, comprising forming an additional mask over the etch mask stack, forming a sidewall layer over the additional mask, etching a second set of features at least partially into the etch mask stack. A plurality of features is etched into the etch layer through the first set of features and the second set of features in the etch mask stack.

Abstract: A method for aligning a reticle is provided. A first patterned layer with a first alignment grid is formed. Sidewall layers are formed over the first patterned layer to perform a first shrink. The first alignment grid after shrink is etched into an etch layer to form an etched first alignment grid. The patterned layer is removed. An optical pattern of a second alignment grid aligned over the etched first alignment grid is measured. The optical pattern is used to determine whether the second alignment grid is aligned over the etched first alignment grid.

Abstract: A plasma reactor comprises a chamber, a bottom electrode, a top electrode, a bottom grounded extension adjacent to and substantially encircling the bottom electrode. The top grounded extension adjacent to and substantially parallel to the top electrode. The top electrode is also grounded. The top grounded extension is capable of being independently raised or lowered to extend into a region above the bottom grounded extension.

Abstract: A method for generating a plurality of reticle layouts is provided. A feature layout with a feature layout pitch is received. A plurality of reticle layouts is generated from the feature layout where each reticle layout of the plurality of reticle layouts has a reticle layout pitch and where each reticle layout pitch is at least twice the feature layout pitch.

Abstract: An apparatus comprising computer readable media is provided. The computer readable media comprises computer readable code for receiving a feature layout and computer readable code for applying shrink correction on the feature layout. The computer readable code for applying the shrink correction comprises providing corner cutouts, adjusting line width and length, shape modifications, etc. for forming features in a patterned layer.

Abstract: A method for etching a dielectric layer over a substrate is provided. A photoresist mask is formed over the dielectric layer. The substrate is placed in a plasma processing chamber. An etchant gas comprising NF3 is provided into the plasma chamber. A plasma is formed from the NF3 gas. The dielectric layer is etched through the photoresist mask with the plasma from the NF3 gas.

Abstract: A method for forming features in an etch layer is provided. A first mask is formed over the etch layer where the first mask defines a plurality of spaces with widths. The first mask is laterally etched where the etched first mask defines a plurality of spaces with widths that are greater than the widths of the spaces of the first mask. A sidewall layer is formed over the etched first mask where the sidewall layer defines a plurality of spaces with widths that are less than the widths of the spaces defined by the etched first mask. Features are etched into the etch layer through the sidewall layer, where the features have widths that are smaller than the widths of the spaces defined by the etched first mask. The mask and sidewall layer are removed.

Abstract: A method for etching a feature in an etch layer is provided. A patterned photoresist mask is formed over the etch layer with photoresist features with sidewalls wherein the sidewalls of the photoresist features have striations forming peaks and valleys. The striations of the sidewalls of the photoresist features are reduced. The reducing the striations comprises at least one cycle, wherein each cycle comprises etching back peaks formed by the striations of the sidewalls of the photoresist features and depositing on the sidewalls of the photoresist features. Features are etched into the etch layer through the photoresist features. The photoresist mask is removed.

Abstract: A method for forming features in an etch layer is provided. A first mask is formed over the etch layer wherein the first mask defines a plurality of spaces with widths. A sidewall layer is formed over the first mask. Features are etched into the etch layer through the sidewall layer, wherein the features have widths that are smaller than the widths of the spaces defined by the first mask. The mask and sidewall layer are removed. An additional mask is formed over the etch layer wherein the additional mask defines a plurality of spaces with widths. A sidewall layer is formed over the additional mask. Features are etched into the etch layer through the sidewall layer, wherein the widths that are smaller than the widths of the spaces defined by the first mask. The mask and sidewall layer are removed.