One aspect of the present disclosure provides a boron nitride powder containing agglomerated particles formed by agglomeration of primary particles of hexagonal boron nitride, in which a degree of purity is 98.5% by mass or more, and a number of particles having a magnetizing ability is 10 or less per 10 g of the boron nitride powder.

One aspect of the present disclosure provides a boron nitride powder containing agglomerated particles formed by agglomeration of primary particles of hexagonal boron nitride, in which a degree of purity is 98.5% by mass or more, and a concentration of elutable impurities is 700 ppm or less.

The technology subject of the present application concerns methods and systems for manufacturing and producing stable polarized or ferroelectric layered materials.

A metamaterial structure and a forming method thereof are provided. The metamaterial structure according to embodiments of the present invention comprises first metamaterial unit structures and second metamaterial unit structures, and the first metamaterial unit structures and the second metamaterial unit structures are arranged alternately. The method of forming a metamaterial structure according to embodiments of the present invention comprises forming a first suspension including first metamaterial unit structures formed by exfoliation of a first metamaterial by mixing the first metamaterial and a first solvent, forming a second suspension including second metamaterial unit structures formed by exfoliation of a second metamaterial by mixing the second metamaterial and a second solvent, forming a nanohybrid structure in which the first metamaterial unit structures and the second metamaterial unit structures are arranged alternately by mixing the first suspension and the second suspension and compressing and sintering the nanohybrid structure.

A nanotube dispersion, a nanotube film manufactured using the same, and a manufacturing method thereof are provided. The nanotube dispersion comprises a nanotube, a nanotube dispersant including at least one selected from a compound represented by a chemical formula 1 and a salt thereof, and a solvent including one selected from an organic solvent, water, and a mixture thereof.

Thermal interface materials may be enhanced through the dispersion of refined boron nitride nanotubes (BNNTs) into a polymer matrix material and one or more microfillers. A refined BNNT material may be formed by reducing free boron particle content from an as-synthesized BNNT material, and in some embodiments reducing h-BN content. Reducing these species improves the thermal conductivity of the BNNTs. Refined BNNTs may be deagglomerated to reduce the size and mass of BNNTs in agglomerations when the deagglomerated BNNT material is dispersed into a target polymer matrix material. The deagglomerated BNNT material may be lyophilized prior to dispersion in the matrix material, to retain the deagglomeration benefit following return to solid state. The surface of the deagglomerated BNNT material may be modified, with one or more functional groups that improve dispersibility and heat transfer in the target polymer matrix material.

A boron nitride powder having a voltage density of not less than +1 V/g as measured by a triboelectric charging test.

A composition (or an aggregate) comprising a h-BN/BNNT structure that comprises a boron nitride nanotube structure and at least a first hexagonal boron nitride structure. Also, a composition comprising at least a first epitaxial h-BN/BNNT structure and at least one metal adhered to the first epitaxial h-BN/BNNT structure. Also, a composition (or an aggregate) that comprises independent boron nitride nanotubes, in which a total mass percentage of independent hexagonal boron nitride and residual boron in the composition is not more than 35%. Also, a material comprising at least a first hexagonal boron nitride structure and at least a first boron nitride nanotube structure, wherein atoms in the first hexagonal boron nitride structure are epitaxially aligned with atoms in the first boron nitride nanotube structure that are closest to the first hexagonal boron nitride structure.

A microstructure comprises a plurality of interconnected units wherein the units are formed of hexagonal boron nitride (h-BN) tubes. The graphene tubes may be formed by photo-initiating the polymerization of a monomer in a pattern of interconnected units to form a polymer microlattice, removing unpolymerized monomer, coating the polymer microlattice with a metal, removing the polymer microlattice to leave a metal microlattice, depositing an h-BN precursor on the metal microlattice, converting the h-BN precursor to h-BN, and removing the metal microlattice.

Thermal interface materials may be enhanced through the dispersion of refined boron nitride nanotubes (BNNTs) into a polymer matrix material and one or more microfillers. A refined BNNT material may be formed by reducing free boron particle content from an as-synthesized BNNT material, and in some embodiments reducing h-BN content. Reducing these species improves the thermal conductivity of the BNNTs. Refined BNNTs may be deagglomerated to reduce the size and mass of BNNTs in agglomerations when the deagglomerated BNNT material is dispersed into a target polymer matrix material. The deagglomerated BNNT material may be lyophilized prior to dispersion in the matrix material, to retain the deagglomeration benefit following return to solid state. The surface of the deagglomerated BNNT material may be modified, with one or more functional groups that improve dispersibility and heat transfer in the target polymer matrix material.