The invention relates to nickel-coated hexagonal boron nitride nanosheet composite powder, its preparation and high-performance composite ceramic cutting tool material. The composite powder has a core-shell structure with BNNS as the core and Ni as the shell. The self-lubricating ceramic cutting tool material is prepared by wet ball milling mixing and vacuum hot-pressing sintering with a phase alumina as the matrix, tungsten-titanium carbide as the reinforcing phase, nickel-coated hexagonal boron nitride nanosheet composite powder as the solid lubricant and magnesium oxide and yttrium oxide as the sintering aids. The invention also provides preparation methods of the nickel-coated hexagonal boron nitride nanosheet composite powder and the self-lubricating ceramic cutting tool material.

An object of the present invention is to provide a method for easily producing an electroconductive laminate having a three-dimensional shape and having a metal layer disposed thereon (for example, an electroconductive laminate having a three-dimensional shape including a curved surface and a metal layer disposed on the curved surface). Another object of the present invention is to provide a three-dimensional structure with a plated-layer precursor layer, a three-dimensional structure with a patterned plated layer, an electroconductive laminate, a touch sensor, a heat generating member, and a three-dimensional structure. The method for producing an electroconductive laminate of the present invention has a step of obtaining a three-dimensional structure with a plated-layer precursor layer including a three-dimensional structure and a plated-layer precursor layer disposed on the three-dimensional structure and having a functional group capable of interacting with a plating catalyst or a precursor thereof and a polymerizable group; a step of applying energy to the plated-layer precursor layer to form a patterned plated layer; and a step of subjecting the patterned plated layer to a plating treatment to form a patterned metal layer on the plated layer.

A method of making a composite material includes disposing a carbon-based particulate material, such as graphene or carbon nanotubes, in an activation solution and activating surfaces of the carbon-based particulate material using the activation solution. Once the surfaces of the carbon-based particulate material have been activated a metallic coating is applied to the activated surfaces to form a composite material. The composite material is then recovered as a particulate material formed having carbon-based particulate material with a metallic coating that is suitable for fusing together for forming electrical conductors, such as with an additive manufacturing technique.

A method of producing an electroconductive substrate including a base material, and an electroconductive pattern disposed on one main surface side of the base material includes: a step of forming a trench including a bottom surface to which a foundation layer is exposed, and a lateral surface which includes a surface of a trench formation layer, according to an imprint method; and a step of forming an electroconductive pattern layer by growing metal plating from the foundation layer which is exposed to the bottom surface of the trench.

A method for application of a metal on a substrate comprises a) contacting at least a part of the surface of the substrate with at least one initiator, and polymerizable units with the ability to undergo a chemical reaction to form a polymer, the polymer comprising at least one charged group, wherein the contacting is achieved by contacting a pad with a plate comprising the at least one initiator and the polymerizable units and subsequently contacting the pad with the surface of the substrate, thereby transferring the at least one initiator and the polymerizable units to the surface of the substrate. Subsequently a metal layer is produced on the surface. The compactness of the applied metal layer is increased.

A substrate W having a non-plateable material portion 31 and a plateable material portion 32 formed on a surface thereof is prepared, and then, a catalyst is imparted selectively to the plateable material portion 32 by supplying a catalyst solution N1 onto the substrate W. Thereafter, a plating layer 35 is selectively formed on the plateable material portion 32 by supplying a plating liquid M1 onto the substrate W. A pH of the catalyst solution N1 is previously adjusted such that the plating layer 35 is suppressed from being precipitated on the non-plateable material portion 31 while being facilitated to be precipitated on the plateable material portion 32.

A method of producing an electroconductive substrate including a base material, and an electroconductive pattern disposed on one main surface side of the base material includes: a step of forming a trench including a bottom surface to which a foundation layer is exposed, and a lateral surface which includes a surface of a trench formation layer, according to an imprint method; and a step of forming an electroconductive pattern layer by growing metal plating from the foundation layer which is exposed to the bottom surface of the trench.

There is provided a copper foil with a carrier particularly suitable for a circuit forming process for removing a carrier after laser drilling and desmear treatment, in detail, a copper foil with a carrier having high heat press resistance (heat resistance) of the carrier, laser drilling performance, corrosion resistance of the carrier against the desmear treatment, corrosion resistance of a release layer against the desmear treatment, and carrier release strength. The copper foil with a carrier comprises a carrier comprising at least one resin selected from polyethylene naphthalate (PEN) resins, polyethersulfone (PES) resins, polyimide resins, and polyphenylene sulfide resins; a silicon layer provided on the carrier, the silicon layer mainly containing silicon; a carbon layer provided on the silicon layer, the carbon layer mainly containing carbon; and an extremely thin copper layer provided on the carbon layer.

A substrate processing apparatus can suppress particle generation on a substrate, and can reduce a consumption amount of a processing liquid. A substrate processing apparatus 1 includes a processing chamber 30 having a processing space 31 in which a substrate W is processed; a vaporizing tank 60, configured to store the processing liquid therein, having a vaporization space 61 in which the stored processing liquid is allowed to be vaporized; a decompression driving unit 70 configured to decompress the vaporization space 61; and a control unit 18. The control unit 18 vaporizes the processing liquid into the processing gas by decompressing the vaporization space 61 without through the processing space 31, and then, vaporizes the processing liquid into the processing gas by decompressing the vaporization space 61 through the processing space 31, and supplies an inert gas into the vaporization space 61.

The method for producing noble metal nanocomposites involves reducing noble metal ions (Ag, Au and Pt) on graphene oxide (GO) or carbon nanotubes (CNT) by using Artocarpus integer leaves extract as a reducing agent. As synthesized MNPs/GO and MNPs/CNT composites have been characterized using X-ray diffraction (XRD), transmission electron microscope (TEM) imaging, and energy dispersive X-ray spectroscopy (EDX). The TEM images of prepared materials showed that the nanocomposites were 1-30 nm in size with spherical nanoparticles embedded on the surface of GO and CNT. This synthetic route is easy and rapid for preparing a variety of nanocomposites. The method avoids use of toxic chemicals, and the prepared nanocomposites can be used for biosensor, fuel cell, and biomedical applications.