Abstract: An integrated circuit has a doped silicon semiconductor with regions of insulators and bare silicon. The bare silicon regions are isolated from other bare silicon regions. A semiconductor device on the doped silicon semiconductor has at least two electrical connections to form regions of patterned metal. A metal is electroplated directly on each of the regions of patterned metal to form plated connections without a seed layer. A self-aligned silicide is located under each plated connection, formed by annealing, for the regions of plated metal on bare silicon.

Abstract: A perpendicular magnetic recording disk includes a template layer below a Ru or Ru alloy underlayer, with a granular Co alloy recording layer formed on the underlayer. substrate. The template layer comprises nanoparticles spaced-apart and partially embedded within a polymer material, with the nanoparticles protruding above the surface of the polymer material. A seed layer covers the surface of the polymer material and the protruding nanoparticles and an underlayer of Ru or a Ru alloy covers the seed layer. The protruding nanoparticles serve as the controlled nucleation sites for the Ru or Ru alloy atoms. The nanoparticle-to-nanoparticle distances can be controlled during the formation of the template layer. This enables control of the Co alloy grain diameter distribution as well as grain-to-grain distance distribution.

Abstract: A method for directed self-assembly (DSA) of block copolymers (BCPs) uses a BCP blend with a small portion of functional homopolymers, called “inks”, before deposition and annealing of the BCP. A substrate has a patterned sublayer formed on it. The BCP blend is deposited on the patterned sublayer and annealed. The BCP blend is guided by the sublayer pattern. The inks selectively distribute into blocks, and part of the inks graft on the substrate underneath the blocks. The BCP blend layer is rinsed away, leaving the grafted inks. The grafted inks form a chemical contrast pattern that has the same geometry with the BCP bulk morphology. This process is repeated, which results in the grafted inks forming a thicker and denser chemical contrast pattern. This chemical contrast pattern of grafted inks is used for the DSA of a BCP that self-assembles as lamellae perpendicular to the substrate.

Abstract: A continuous-media perpendicular magnetic recording disk has a granular recording layer (RL) with controlled grain pitch distribution and controlled long range ordering of the grains. The disk includes a substrate with a template layer for the RL that comprises a blend of at least two different sized nanoparticles. The nanoparticles have a nanoparticle core with attached polymer ligands. The nanoparticle cores protrude above the surface of the template layer to provide a nonplanar surface topology. The blend of two sizes of nanoparticles causes the RL to have low grain pitch distribution and a disruption of long range ordering so that there are no large magnetic rafts. One of the nanoparticles types has a diameter greater than 105% of the diameter of the other nanoparticle type and is present in the total blend of nanoparticles of between about 5% and 35% or between about 55% and 90%.

Abstract: A floor cleaning machine having a movable adjustment element, a suction foot, a cleaning head and a drive. The adjustment element is coupled to the cleaning head, the suction foot and the drive. The drive is configured to move the adjustment element between a first position, in which the cleaning head and suction foot are raised, a second position, in which the cleaning head is raised and the suction foot is lowered, and a third position in which the cleaning head and suction foot are lowered.

Abstract: Methods of administering immunoconjugates that bind to CD37 are provided. The methods comprise administering an anti-CD37 immunoconjugate to a person in need thereof, for example, a cancer patient, at a therapeutically effective dosing regimen that results in minimal adverse effects.

Abstract: A suction foot for a floor cleaning machine having an outer body, which has side pieces having an L-shaped longitudinal cross-section comprising a first horizontal side piece and a second vertical side piece, which extends perpendicular to the first side piece, having an inner body, which is releasably attached to the outer body. The inner body is coupled to the outer body with a sliding movement that is perpendicular to the first horizontal side piece and parallel to the second vertical side piece. A tension band is provided to press a sealing strip against the inner body. The ends of the tension band engage with the ends of the inner body.

Abstract: Methods to pattern substrates with dense periodic nanostructures that combine top-down lithographic tools and self-assembling block copolymer materials are provided. According to various embodiments, the methods involve chemically patterning a substrate, depositing a block copolymer film on the chemically patterned imaging layer, and allowing the block copolymer to self-assemble in the presence of the chemically patterned substrate, thereby producing a pattern in the block copolymer film that is improved over the substrate pattern in terms feature size, shape, and uniformity, as well as regular spacing between arrays of features and between the features within each array compared to the substrate pattern. In certain embodiments, the density and total number of pattern features in the block copolymer film is also increased. High density and quality nanoimprint templates and other nanopatterned structures are also provided.

Abstract: In directed self-assembly (DSA) of a block copolymer (BCP), a patterned sublayer on a substrate serves as a guiding chemical prepattern on which BCPs form more uniform and/or denser patterns. A layer of a blend of a BCP and functional homopolymers, referred to as inks, is deposited on the patterned sublayer and annealed to change the initial chemical prepattern to a 1:1-like chemical pattern that is more favorable to DSA. After annealing, the inks selectively distribute into blocks by DSA, and part of the inks graft on the substrate underneath the blocks. The BCP blend layer is then rinsed away, leaving the grafted inks. A second layer of BCP is then deposited and annealed as a second DSA step to form alternating lines of the BCP components. One of the BCP components is removed, leaving lines of the other BCP component as a mask for patterning the substrate.

Abstract: In one embodiment, a system for solvent annealing of a block copolymer film includes a solvent annealing chamber, and a controller configured to control at least one processing parameter for inducing a super-saturation of a solvent in an atmosphere within the solvent annealing chamber. In another embodiment, a method for solvent annealing of a block copolymer film includes inducing a super-saturation of a solvent in an atmosphere within a solvent annealing chamber having a block copolymer film therein for inducing formation of polymeric domains.

Abstract: A method for directed self-assembly (DSA) of block copolymers (BCPs) uses a BCP blend with a small portion of functional homopolymers, called “inks”, before deposition and annealing of the BCP. A substrate has a patterned sublayer formed on it. The BCP blend is deposited on the patterned sublayer and annealed. The BCP blend is guided by the sublayer pattern. The inks selectively distribute into blocks, and part of the inks graft on the substrate underneath the blocks. The BCP blend layer is rinsed away, leaving the grafted inks. The grafted inks form a chemical contrast pattern that has the same geometry with the BCP bulk morphology. This process is repeated, which results in the grafted inks forming a thicker and denser chemical contrast pattern. This chemical contrast pattern of grafted inks is used for the DSA of a BCP that self-assembles as lamellae perpendicular to the substrate.

Abstract: Block copolymers (BCPs) and synthetic infiltration synthesis (SIS) are used to double the line density on a substrate. The BCP comprises first and second interconnected BCP components with a functional group at the junction or interface of the components. After deposition of the BCP on the substrate and annealing, a pattern of parallel stripes of first and second BCP components is formed with a pattern of functional group interfaces between the components. Each of the BCP components is non-reactive with atomic layer deposition (ALD) precursors, while the functional group is reactive with the ALD precursors. The ALD results in the infiltration of inorganic material into the interfaces where the reactive functional groups are located but without affecting the BCP components. After removal of the organic material, a pattern of parallel lines of inorganic material remains with a pitch half that of the stripes of BCP components.

Abstract: A continuous-media perpendicular magnetic recording disk has a granular recording layer (RL) with controlled grain pitch distribution and controlled long range ordering of the grains. The disk includes a substrate with a template layer for the RL that comprises a blend of at least two different sized nanoparticles. The nanoparticles have a nanoparticle core with attached polymer ligands. The nanoparticle cores protrude above the surface of the template layer to provide a nonplanar surface topology. The blend of two sizes of nanoparticles causes the RL to have low grain pitch distribution and a disruption of long range ordering so that there are no large magnetic rafts. One of the nanoparticles types has a diameter greater than 105% of the diameter of the other nanoparticle type and is present in the total blend of nanoparticles of between about 5% and 35% or between about 55% and 90%.

Abstract: In directed self-assembly (DSA) of a block copolymer (BCP), a patterned sublayer on a substrate serves as a guiding chemical prepattern on which BCPs form more uniform and/or denser patterns. A layer of a blend of a BCP and functional homopolymers, referred to as inks, is deposited on the patterned sublayer and annealed to change the initial chemical prepattern to a 1:1-like chemical pattern that is more favorable to DSA. After annealing, the inks selectively distribute into blocks by DSA, and part of the inks graft on the substrate underneath the blocks. The BCP blend layer is then rinsed away, leaving the grafted inks. A second layer of BCP is then deposited and annealed as a second DSA step to form alternating lines of the BCP components. One of the BCP components is removed, leaving lines of the other BCP component as a mask for patterning the substrate.

Abstract: In directed self-assembly (DSA) of a block copolymer (BCP), a patterned sublayer on a substrate serves as a guiding chemical prepattern on which BCPs form more uniform and/or denser patterns. A layer of a blend of a BCP and functional homopolymers, referred to as inks, is deposited on the patterned sublayer and annealed to change the initial chemical prepattern to a 1:1-like chemical pattern that is more favorable to DSA. After annealing, the inks selectively distribute into blocks by DSA, and part of the inks graft on the substrate underneath the blocks. The BCP blend layer is then rinsed away, leaving the grafted inks A second layer of BCP is then deposited and annealed as a second DSA step to form alternating lines of the BCP components. One of the BCP components is removed, leaving lines of the other BCP component as a mask for patterning the substrate.

Abstract: The disclosure relates generally to a method for fabricating a patterned medium. The method includes providing a substrate with an exterior layer under a lithographically patterned surface layer, the lithographically patterned surface layer comprising a first pattern in a first region and a second pattern in a second region, applying a first masking material over the first region, transferring the second pattern into the exterior layer in the second region, forming self-assembled block copolymer structures over the lithographically patterned surface layer, the self-assembled block copolymer structures aligning with the first pattern in the first region, applying a second masking material over the second region, transferring the polymer block pattern into the exterior layer in the first region, and etching the substrate according to the second pattern transferred to the exterior layer in the second region and the polymer block pattern transferred to the exterior layer in the first region.

Abstract: In directed self-assembly (DSA) of a block copolymer (BCP), a patterned sublayer on a substrate serves as a guiding chemical prepattern on which BCPs form more uniform and/or denser patterns. A layer of a blend of a BCP and functional homopolymers, referred to as inks, is deposited on the patterned sublayer and annealed to change the initial chemical prepattern to a 1:1-like chemical pattern that is more favorable to DSA. After annealing, the inks selectively distribute into blocks by DSA, and part of the inks graft on the substrate underneath the blocks. The BCP blend layer is then rinsed away, leaving the grafted inks A second layer of BCP is then deposited and annealed as a second DSA step to form alternating lines of the BCP components. One of the BCP components is removed, leaving lines of the other BCP component as a mask for patterning the substrate.

Abstract: A method for sidewall spacer line doubling uses sacrificial sidewall spacers. A mandrel layer is deposited on a substrate and patterned into mandrel stripes with a pitch double that of the desired final line pitch. A functionalized polymer is deposited over the mandrel stripes and into the gaps between the stripes. The functionalized polymer has a functional group that reacts with the surface of the mandrel stripes when heated to graft a monolayer of polymer brush material onto the sidewalls of the mandrel stripes. A layer of etch mask material is deposited into the gaps between the polymer brush sidewall spacers to form interpolated stripes between the mandrel stripes. The polymer brush sidewall spacers are removed, leaving on the substrate a pattern of mandrel stripes and interpolated stripes with a pitch equal to the desired final line pitch. The stripes function as a mask to etch the substrate.

Abstract: A method for making a film of core-shell nanoparticles generally uniformly arranged on a substrate uses atomic layer deposition (ALD) to form the shells. The nanoparticle cores are placed in a solution containing a polymer having an end group for attachment to the cores. The solution is then applied to a substrate and allowed to dry, resulting in the nanoparticle cores being uniformly arranged by the attached polymer chains. ALD is then used to grow the shell material on the cores, using two precursors for the shell material that are non-reactive with the polymer. The polymer chains also form between the cores and the substrate surface, so the ALD forms shell material completely surrounding the cores. The uniformly arranged core-shell nanoparticles can be used as an etch mask to etch the substrate.

Abstract: According to one embodiment, a patterned magnetic storage medium is disclosed herein. The magnetic storage medium includes a pattern formed on a substrate. The pattern includes at least a first and second feature and an edge defined between the first and second features. Additionally, the magnetic storage medium includes a magnetic layer formed on the pattern. The magnetic layer includes grains separated by a non-magnetic segregant boundary. The segregant boundary is positioned above the edge of the pattern.