Provided is a conductive paste which makes it possible to form a conductive layer having excellent conductivity even when spherical copper powder having a small particle diameter is used. Disclosed is a conductive paste containing a conductive filler and a binder resin. In this conductive paste, when a first coating film is prepared by coating a first paste containing 100 parts by weight of the binder resin and 20 parts by weight of the conductive filler on a first substrate at a coating amount of 100 g/m.sup.2 and drying and curing the binder resin, the first coating film has a light transmittance of 20% or more, and when a second coating film is prepared by coating a second paste containing the binder resin but not containing the conductive filler on a second substrate at a coating amount equivalent to a dry solid content of 55 g/m.sup.2 and drying and curing the binder resin, a film thickness t μm of the second coating film and a shrinkage ratio α % obtained by the following formula (1) satisfy a relationship of the following formula (2): α=(1−(arc length of a surface of the second coating film after drying and curing)/(arc length of a second substrate after drying and curing))×100 Formula (1) and α≥(5t+50)×10.sup.−3 Formula (2).

A selective laser sintering system includes a leveling roller having a first orientation. The leveling roller is configured to roll over a first feed bin. The build chamber is configured to receive, from the first feed bin and by the leveling roller, a transfer of a portion of matrix material. The selective laser sintering system is configured to transfer the portion to the build chamber in a number of orientations.

A method of additive manufacturing is provided. The method includes depositing a layer of base material from which an additively manufactured part is produced. The method also includes depositing a slurry onto the layer of base material, where the slurry includes a solvent, particles of a structural material, and a reinforcing agent.

A solid-state manufacturing system having a sleeve having a hollow portion for receiving a feedstock material; a friction die rotatably coupled adjacent an end of the sleeve, the friction die and the sleeve being rotatable relative to each other along a rotation axis and configured to generate frictional heat to heat at least a portion of the feedstock material within the hollow portion of the sleeve to a malleable state; a propulsion system operably coupled to the sleeve configured to urge the feedstock material in a processing direction along the rotational axis; and an extrusion hole configured to permit the malleable feedstock material to be extruded from the extrusion hole in response to the propulsion system. A solid-state manufacturing method similarly configured is provided.

A solid-state manufacturing system having a sleeve having a hollow portion for receiving a feedstock material; a friction die rotatably coupled adjacent an end of the sleeve, the friction die and the sleeve being rotatable relative to each other along a rotation axis and configured to generate frictional heat to heat at least a portion of the feedstock material within the hollow portion of the sleeve to a malleable state; a propulsion system operably coupled to the sleeve configured to urge the feedstock material in a processing direction along the rotational axis; and an extrusion hole configured to permit the malleable feedstock material to be extruded from the extrusion hole in response to the propulsion system. A solid-state manufacturing method similarly configured is provided.

The present invention provides a method of manufacturing a single-walled-carbon-nanotube-reinforced metal matrix complex material. The method includes (a) manufacturing a complex powder by performing ball milling of a metal powder and a single-walled carbon nanotube powder, and (b) manufacturing a metal-carbon-nanotube complex material by spark-plasma-sintering (SPS) the complex powder manufactured during step (a). According to the method of manufacturing the single-walled-carbon-nanotube-reinforced metal matrix complex material according to the present invention, in order to manufacture material parts requiring high strength and abrasion resistance, the single-walled carbon nanotube powder is added to various metal matrixes and ball milling is performed, thus manufacturing a complex powder having uniform dispersity. The manufactured complex powder is subjected to complexation in a short period of time using a spark-plasma-sintering (SPS) process, thereby easily manufacturing a bulk-type single-walled-carbon-nanotube-reinforced metal matrix complex material having excellent physical properties.

Disclosed is a method of forming a treated material. The method includes providing a high-speed blender; adding a solvent and brass granules to the blender and blending at high speed until mixed; adding copper granules to the blender and mixing at high speed until mixed; adding carbon nanotubes and graphene to the blender and mixing until blended. The mixture of solvent, brass granules, copper granules, carbon granules, carbon nanotubes, and graphene are added to an additional mixture of brass and copper and mixed until all of the granules are uniformly saturated. The mixture is then dried to a powder. Thereafter, the dry powder may be added to ferrous or nonferrous metal(s) in a high temperature crucible and then heated until melted.

A metal matrix composite comprising nanotubes; a method of producing the same; and a composition, for example a metal alloy, used in such composites and methods, are disclosed. A method for continuously infiltrating nanotube yarns, tapes or other nanotube preforms with metal alloys using a continuous process or a multistep process, which results in a metal matrix composite wire, cable, tape, sheet, tube, or other continuous shape, and the microstructure of these infiltrated yarns or fibers, are disclosed. The nanotube yarns comprise a multiplicity of spun nanotubes of carbon (CNT), boron nitride (BNNT), boron (BNT), or other types of nanotubes. The element that infiltrates the nanotube yarns or fibers can, for example, be alloyed with a concentration of one or more elements chosen such that the resulting alloy, in its molten state, will exhibit improved wetting of the nanotube material.

Disclosed herein are embodiments of compositions for gas sensing and sensors utilizing the same. In one embodiment, a composition comprises carbon nanotubes and polymer-coated metal nanoparticles bound to the carbon nanotubes.

Disclosed herein are embodiments of compositions for gas sensing and sensors utilizing the same. In one embodiment, a composition comprises carbon nanotubes and polymer-coated metal nanoparticles bound to the carbon nanotubes.