A type of composite material where the matrix material and additive are held together by covalently or non-covalently bound ligands is described. A particularly useful composite material covered by the present invention is a carbon nanotube-reinforced composite material where the matrix consists of a polymer, covalently attached to a linker, where said linker is non-covalently attached to the carbon nanotube. Methods for the preparation of such composite materials are provided.

A method of fabricating a carbon-carbon composite includes mixing a carbon-based matrix precursor with a carbon nanomaterial additive forming a polymeric matrix impregnated with the carbon nanomaterial additive, heating the impregnated polymeric matrix under an inert atmosphere, with temperatures ranging between 350-1100° C. for carbonization followed by graphitization at a temperature greater than 1800° C. The matrix precursor may be a graphitizing or non-graphitizing material. The additive may present basal or edge site carbon atoms or a combination of both. As a result, a carbon-carbon composite composed of the matrix and additive is formed by templating or bond formation, wherein at least 1-D nano-scale or micro-scale structural changes begins at the interface between the matrix and additive and propagates outward from the interface into the matrix, thus adjusting or altering the nano- or micro-structures in the matrix that would not naturally occur in the absence of the additive.

A material useful as a proppant comprises a core chemically reacted in situ from coal dust and a polymer derived ceramic material, such that at least a portion of the coal dust is chemically converted to a ceramic, nanoparticles, graphene, nanofibers or combinations of any of these.

PDC resins are mixed with various sources of carbon to form electrodes through pyrolysis of the mixture of PDC resins and coal dust derived materials with or without other sources of carbon, substrates and the like. For example, a PDC resin-coal dust mixture produces a material for use as an anode in lithium ion batteries and supercapacitors when pyrolyzed to form a porous, electrically conductive ceramic composite.

A type of composite material where the matrix material and additive are held together by covalently or non-covalently bound ligands is described. A particularly useful composite material covered by the present invention is a carbon nanotube-reinforced composite material where the matrix consists of a polymer, covalently attached to a linker, where said linker is non-covalently attached to the carbon nanotube.

Methods for the preparation of such composite materials are provided.

Methods and apparatuses for additive manufacturing are described. A method for additive manufacturing may include exposing a layer of material on a build surface to one or more projections of laser energy including at least one line laser having a substantially linear shape. The intensity of the line laser may be modulated so as to cause fusion of the layer of material according to a desired pattern as the one or more projections of laser energy are scanned across the build surface.

The present disclosure provides a wave-to-heat conversion structure. The wave-to-heat conversion structure is a loose tissue formed by a plurality of intersect and hooking fibrous structures. The loose tissue retains a dendritic structure of the fibrous structure, and a plurality of micro-gaps are formed between the fibrous structures. The wave-to-heat conversion structure further includes a heat conductive layer, and the heat conduction coefficient of the heat conductive layer is ranged from about 10 W/m.Math.K to 3000 W/m.Math.K. The present disclosure provides a wave-to-heat conversion spectrum plate using the wave-to-heat conversion structure.

A type of composite material where the matrix material and additive are held together by covalently or non-covalently bound ligands is described. A particularly useful composite material covered by the present invention is a carbon nanotube-reinforced composite material where the matrix consists of a polymer, covalently attached to a linker, where said linker is non-covalently attached to the carbon nanotube. Methods for the preparation of such composite materials are provided.

A carbon nanotube (CNT) sheet containing CNTs, arranged is a randomly oriented, uniformly distributed pattern, and having a basis weight of at least 1 gsm and a relative density of less than 1.5. The CNT sheet is manufactured by applying a CNT suspension in a continuous pool over a filter material to a depth sufficient to prevent puddling of the CNT suspension upon the surface of the filter material, and drawing the dispersing liquid through the filter material to provide a uniform CNT dispersion and form the CNT sheet. The CNT sheet is useful in making CNT composite laminates and structures having utility for electro-thermal heating, electromagnetic wave absorption, lightning strike dissipation, EMI shielding, thermal interface pads, energy storage, and heat dissipation.

This document describes processes for preparing ceramics, especially lithium-based ceramics. The ceramics produced by this process and their use in electrochemical applications are also described as well as electrode materials, electrodes, electrolyte compositions, and electrochemical cells comprising them.