Embodiments described herein relate generally to large scale synthesis of thinned graphite and in particular, few layers of graphene sheets and graphene-graphite composites. In some embodiments, a method for producing thinned crystalline graphite from precursor crystalline graphite using wet ball milling processes is disclosed herein. The method includes transferring crystalline graphite into a ball milling vessel that includes a grinding media. A first and a second solvent are transferred into the ball milling vessel and the ball milling vessel is rotated to cause the shearing of layers of the crystalline graphite to produce thinned crystalline graphite.

Compositions comprising hydrogenated and dehydrogenated graphite comprising a plurality of flakes. At least one flake in ten has a size in excess of ten square micrometers. For example, the flakes can have an average thickness of 10 atomic layers or less.

A structured substrate includes a substrate body having an active side. The substrate body includes reaction cavities that open along the active side and interstitial regions that separate the reaction cavities. The structured substrate includes an ensemble amplifier positioned within each of the reaction cavities. The ensemble amplifier includes a plurality of nanostructures configured to at least one of amplify electromagnetic energy that propagates into the corresponding reaction cavity or amplify electromagnetic energy that is generated within the corresponding reaction cavity.

A structured substrate includes a substrate body having an active side. The substrate body includes reaction cavities that open along the active side and interstitial regions that separate the reaction cavities. The structured substrate includes an ensemble amplifier positioned within each of the reaction cavities. The ensemble amplifier includes a plurality of nanostructures configured to at least one of amplify electromagnetic energy that propagates into the corresponding reaction cavity or amplify electromagnetic energy that is generated within the corresponding reaction cavity.

A method for inserting 2D flakes of a two dimensional material into pores of a porous substrate comprises providing a porous substrate having a plurality of open pores, wherein at least some of the pores contain a gas, applying a liquid dispersion of flexible 2D flakes of a two dimensional material to the porous substrate; subjecting said porous substrate and said liquid dispersion to a vacuum, such that the gas is evacuated from the pores, causing the liquid dispersion to be introduced into the pores and removing the liquid from the pores, so as to leave the 2D flakes in the pores.

A method for inserting 2D flakes of a two dimensional material into pores of a porous substrate comprises providing a porous substrate having a plurality of open pores, wherein at least some of the pores contain a gas, applying a liquid dispersion of flexible 2D flakes of a two dimensional material to the porous substrate; subjecting said porous substrate and said liquid dispersion to a vacuum, such that the gas is evacuated from the pores, causing the liquid dispersion to be introduced into the pores and removing the liquid from the pores, so as to leave the 2D flakes in the pores.

Proposed is a three-dimensional chiral metal nanoparticle, comprising a heterometal nanoparticle including: a seed region formed of a first metal; and a heterogeneous region disposed on an external side of the seed region to enclose the seed region and formed of a second metal. The first metal is gold (Au), and the second metal is palladium (Pd). In a rectangular parallelepiped structure, a rectangular band shape rotates in a clockwise direction or a counterclockwise direction on each surface and protrudes towards a center of the surface.

The present disclosure relates generally to thin metal films having an ultra-flat surface and methods of their preparation. In particular, the ultra-flat thin metal films comprise FCC metals. Preferably, the thin metal films are attached to a substrate. Preferred substrates comprise chalcogenides and dichalcogenides. Beneficially, the thin metal films described herein can be prepared at ambient temperatures.

A manufacturing method of a quantum dot ensemble of the present disclosure is a manufacturing method of a quantum dot ensemble including a plurality of core-shell quantum dots 10A that each includes a core 10B including a compound semiconductor, and a shell 10C including a compound semiconductor and covering the core, and a ligand 10D coordinated to the shell, and the manufacturing method includes mixing a core material, a shell material, and the ligand in a solvent and thereafter performing heating to thereby form the core-shell quantum dots, coordinate the ligand to the shell, and cleave the ligand.

A manufacturing method of a quantum dot ensemble of the present disclosure is a manufacturing method of a quantum dot ensemble including a plurality of core-shell quantum dots 10A that each includes a core 10B including a compound semiconductor, and a shell 10C including a compound semiconductor and covering the core, and a ligand 10D coordinated to the shell, and the manufacturing method includes mixing a core material, a shell material, and the ligand in a solvent and thereafter performing heating to thereby form the core-shell quantum dots, coordinate the ligand to the shell, and cleave the ligand.