Described herein are the depositions of conductive metallic films on a surface which contains topography. The deposition uses a metallic precursor comprises a neutral (uncharged) metal compound in which the metal atom is in the zerovalent state and stabilized by ligands which are stable as uncharged, volatile species.

The present invention generally relates to nanoscale wires, and to methods of producing nanoscale wires. In some aspects, the nanoscale wires are nanowires comprising a core which is continuous and a shell which may be continuous or discontinuous, and/or may have regions having different cross-sectional areas. In some embodiments, the shell regions are produced by passing the shell material (or a precursor thereof) over a core nanoscale wire under conditions in which Plateau-Raleigh crystal growth occurs, which can lead to non-homogenous deposition of the shell material on different regions of the core. The core and the shell each independently may comprise semiconductors, and/or non-semiconductor materials such as semiconductor oxides, metals, polymers, or the like. Other embodiments are generally directed to systems and methods of making or using such nanoscale wires, devices containing such nanoscale wires, or the like.

Systems and methods for depositing a thin film layer onto a flexible ferromagnetic substrate include a porous block in a deposition zone and a plurality of magnets embedded within the porous block. The magnets provide a downward force on a flexible ferromagnetic substrate being transported over the porous block, e.g., in a reel-to-reel system. Pressurized gas is forced upward through the porous block, providing an upward force that balances the downward force and supports the substrate at a desired height above the porous block. The substrate is thus held flat during transport through the deposition zone, enabling uniform deposition of a thin film layer.

Systems and methods for depositing a thin film layer onto a flexible ferromagnetic substrate include a porous block in a deposition zone and a plurality of magnets embedded within the porous block. The magnets provide a downward force on a flexible ferromagnetic substrate being transported over the porous block, e.g., in a reel-to-reel system. Pressurized gas is forced upward through the porous block, providing an upward force that balances the downward force and supports the substrate at a desired height above the porous block. The substrate is thus held flat during transport through the deposition zone, enabling uniform deposition of a thin film layer.

The present invention is a copper film-forming agent containing a copper complex composed of a copper formate and a 5-membered or 6-membered nitrogen-containing heterocyclic compound having from 1 to 3 nitrogen atoms, in which the nitrogen-containing heterocyclic compound has one or two ring structures, the total number of carbon atoms contained in a substituent is from 1 to 5, and an element other than a carbon atom in the compound is not bonded to a hydrogen atom.

The present invention is a copper film-forming agent containing a copper complex composed of a copper formate and a 5-membered or 6-membered nitrogen-containing heterocyclic compound having from 1 to 3 nitrogen atoms, in which the nitrogen-containing heterocyclic compound has one or two ring structures, the total number of carbon atoms contained in a substituent is from 1 to 5, and an element other than a carbon atom in the compound is not bonded to a hydrogen atom.

Electrically-conductive silver metal is provided in a pattern on a substrate having a first supporting side and a second opposing supporting side. One or both of the first supporting side and the second opposing supporting side has one or more electrically-conductive silver metal containing patterns containing the electrically-conductive silver metal; an -oxy carboxylate; a 5- or 6-membered N-heteroaromatic compound; and a polymer that is either (i) a hydroxy-containing cellulosic polymer or (ii) a non-cellulosic acrylic polymer having a halo- or hydroxy-containing side chain. Such articles can be used in various devices and electrodes.

An additive manufacturing process for forming a metallic layer on the surface of the substrate includes fabricating a substrate from a polymerizable composition by a stereolithographic process, and contacting the reactive surface with an aqueous solution including a metal precursor. The metal precursor includes a metal, and the polymerizable composition includes a multiplicity of multifunctional components. Each multifunctional component includes a reactive moiety extending from a surface of the substrate to form a reactive surface. An interface between the reactive surface and the aqueous solution is irradiated to form nanoparticles including the metal. The nanoparticles are chemically coupled to the reactive surface by reactive moieties, thereby forming a metallic layer on the surface of the substrate.

Disclosed herein are methods comprising: illuminating a first location of an optothermal substrate with electromagnetic radiation; wherein the optothermal substrate converts at least a portion of the electromagnetic radiation into thermal energy; and wherein the optothermal substrate is in thermal contact with a liquid sample comprising a plurality of thermally reducible metal ions; thereby: generating a confinement region at a location in the liquid sample proximate to the first location of the optothermal substrate; trapping at least a portion of the plurality of thermally reducible metal ions within the confinement region; and thermally reducing the trapped portion of the plurality of thermally reducible metal ions; thereby: depositing a metal particle on the optothermal substrate at the first location. Also disclosed herein are systems for performing the methods described herein. Also disclosed herein are patterned substrates made by the methods described herein, and methods of use thereof.

A method of electrochemical deposition of a metallic material onto a substrate is provided. The method includes providing an alkaline solution of hydroxide ions, immersing a metallic material precursor and the substrate into the alkaline solution to form an electrochemical bath, and electrochemically depositing a textured layer of the metallic material onto the substrate. A method of electrochemical deposition of a textured nanoparticle is provided. The method includes providing an alkaline solution of hydroxide ions, immersing the metallic material into the alkaline solution to form an electrochemical bath, and precipitating the textured nanoparticles from the electrochemical bath. A method of electrochemical deposition of a metallic material onto a nanoparticle is provided. The method includes providing an alkaline solution of hydroxide ions, immersing the metallic material and the nanoparticle into the alkaline solution to form an electrochemical bath, and depositing a textured layer of the metallic material onto the nanoparticle.