In an embodiment, a thermoplastic composite comprises a thermoplastic polymer; and a dielectric filler having a multimodal particle size distribution; wherein a peak of a first mode of the multimodal particle size distribution is at least seven times that of a peak of a second mode of the multimodal particle size distribution; and a flow modifier.

A composite film having a high dielectric permittivity engineered particles dispersed in a high breakdown strength polymer material to achieve high energy density.

In order to provide a thermally conductive polymer-based resin that may be molded using a range of thermoplastic manufacturing techniques, a composition includes a thermoplastic polymer and/or elastomer, a polymer fiber, a binding agent, and a thermally conductive filler. The composition includes from 40 to 80 volume percentage of a thermoplastic polymer and/or a thermoplastic elastomer, from 5 to 30 volume percentage of a polymer fiber, from 0.1 to 20 volume percentage of a binding agent, and from 10 to 40 volume percentage of a thermally conductive filler. The polymer fibers and thermally conductive fillers are combined to create a hybrid thermally conductive particle for better feeding in standard plastic processing methods. The polymer fiber has an aspect ratio greater than 10. The filler has a thermal conductivity greater than or equal to 10 W/m-K. The composition is characterized by a thermal conductivity of at least 1 W/m-K.

A composite structure includes a plurality of laminate layers containing resin reinforced with carbon fiber; and a laminate coated with a metallic layer integrated with a transition metal oxide that is laid up as a topmost layer of the plurality of laminate layers. The plurality of laminate layers and the coated laminate are cured to form a composite material in a defined process to (i) integrate the transition metal oxide in the composite material, (ii) utilize transformed magnetic properties of the transition metal oxide to integrate the transition metal oxide into the metallic layer to coat the laminate, and (iii) utilize transformed optical properties of the transition metal oxide to achieve infrared shielding beyond a phase transition temperature of the transition metal oxide.

A method of forming a polyolefin-perovskite nanomaterial composite which contains oriented electrically and thermally conductive pathways. The method involves milling a polyolefin with particles of a perovskite nanomaterial, molding to forma composite plate, and subjecting the composite plate to an AC voltage. The AC voltage forms oriented electrically and thermally conductive pathways by partial dielectric breakdown of the composite. The presence of the oriented electrically and thermally conductive pathways gives the polyolefin-perovskite nanomaterial electrical and thermal conductivity and dielectric permittivity higher than the polyolefin alone.

A method of manufacturing a molded solid surface includes mixing ferrous particles into a resinous material, injecting the resinous material including the ferrous particles into a mold, the mold including an upper mold half and a lower mold half, creating a predetermined pattern in the resinous material by applying a force to the ferrous particles in the resinous material toward a surface of the upper mold half or the lower mold half using one or more magnets, and curing the resinous material in the mold into the molded solid surface.

There is provided a high-pressure tank manufacturing method that ensures a shorten heating period compared with a conventional one and eliminates a need for taking out a material for heating after heating. A high-pressure tank manufacturing method includes: disposing a conductive heating material on an outer periphery of a resin liner; winding a conductive fiber with which thermosetting resin is impregnated around the outer periphery of the resin liner on which the heating material is disposed; and heating the heating material and the fiber on the outer periphery of the resin liner by induction heating to harden the thermosetting resin.

A method for producing a 3D structure, according g to which a composite conductive substrate (CCS) with a conductive layer and a non-conductive layer is provided and a conductive pattern is determined for each layer of the 3D structure. A first layer of non-conductive matter on the CCS is printed, such that the conductive pattern of the first layer left empty from the non-conductive matter. The empty conductive pattern is filled with conductive matter by electroplating and for each following layer, in turn, printing, on the previous layer, a layer of non-conductive matter, the conductive pattern of the present layer left empty from the non-conductive matter; plating non-conductive areas of the previous layer that are left uncoated with conductive matter; and filling the empty conductive pattern of the present layer with conductive matter by electroplating.

A method for preparing a fully soft self-powered vibration sensor mainly uses a laser carbonization technology to prepare a two-dimensional porous carbon electrode with an origami structure, and then transfers the two-dimensional porous carbon electrode to a three-dimensional polydimethylsiloxane (PDMS) cavity through mold transfer; Finally, a laser engraving technology is used to create microstructures on surfaces of the porous carbon electrode and a PDMS film. The sensor includes the PDMS film, a liquid metal droplet oscillator, a porous out-of-plane carbon electrode, and a 3D PDMS cavity assembled tightly from top to bottom. The sensor works based on the triboelectric nanogenerator principle, when the sensor is excited by vibrations, contact and triboelectrification at an interface of the liquid metal droplet oscillator and PDMS film charge both objects, making contact surfaces carry stable charges, which allows the movement of the liquid metal droplet oscillator to output current through electrostatic induction.

Polymer-based selective radiative cooling structures are provided which include a selectively emissive layer of a polymer or a polymer matrix composite material. Exemplary selective radiative cooling structures are in the form of a sheet, film or coating. Also provided are methods for removing heat from a body by selective thermal radiation using polymer-based selective radiative cooling structures, and a cold collection system comprising a plurality of the polymer-based selective radiative cooling structures.