A thermal interface comprising a polymer composite comprising a polymer and a self-assembled boron arsenide.

In accordance with the purpose(s) of the present disclosure, as embodied and broadly described herein, the disclosure, in one aspect, relates to compound Bi-poor perovskite crystals, methods for making the same, and ionizing and other electromagnetic radiation detectors constructed using the Bi-poor perovskite crystals. The Bi-poor perovskite crystals can be synthesized using melt-based growth methods and solution-based growth methods and contain no toxic heavy metals such as lead, cadmium, thallium, or mercury. Devices fabricated from the crystals maintain acceptable levels of performance over time. In some aspects, post-growth annealing can be used to improve the properties, including, but not limited to, room temperature resistivity and response to radiation.

A method for forming, or crystallising, clathrates hydrates of a host molecule in a liquid including water includes the following consecutive steps: cooling the liquid to a temperature no higher than the crystallisation temperature of the clathrates hydrates; and placing the cooled liquid in contact with host molecules that are capable of forming clathrates hydrates and are adsorbed on a solid support that has a large specific surface area and is made of a hydrophobic and apolar material, whereby the host molecules are desorbed from the solid support that has a large specific surface area and is made of a hydrophobic and apolar material, and react with the water of the liquid in order to provide a liquid containing clathrates hydrates and the solid support.

A method for forming, or crystallising, clathrates hydrates of a host molecule in a liquid including water includes the following consecutive steps: cooling the liquid to a temperature no higher than the crystallisation temperature of the clathrates hydrates; and placing the cooled liquid in contact with host molecules that are capable of forming clathrates hydrates and are adsorbed on a solid support that has a large specific surface area and is made of a hydrophobic and apolar material, whereby the host molecules are desorbed from the solid support that has a large specific surface area and is made of a hydrophobic and apolar material, and react with the water of the liquid in order to provide a liquid containing clathrates hydrates and the solid support.

A process for manufacturing colloidal nanosheet, by lateral growth, on an initial colloidal nanocrystal, of a crystalline semiconductor material represented by the formula M.sub.nX.sub.y, where M is a transition metal and X a chalcogen. The process includes the following steps: The preparation of a first organic solution, non or barely coordinating used as a synthesis solvent and including at least one initial colloidal nanocrystal; The preparation of a second organic solution including precursors of M and X, and including an acetate salt. And the slow introduction over a predetermined time scale of a predetermined amount of the second solution in a predetermined amount of the first solution, at a predetermined temperature for the growth of nanosheets. The use of the obtained material is also presented.

A process for manufacturing colloidal nanosheet, by lateral growth, on an initial colloidal nanocrystal, of a crystalline semiconductor material represented by the formula M.sub.nX.sub.y, where M is a transition metal and X a chalcogen. The process includes the following steps: The preparation of a first organic solution, non or barely coordinating used as a synthesis solvent and including at least one initial colloidal nanocrystal; The preparation of a second organic solution including precursors of M and X, and including an acetate salt. And the slow introduction over a predetermined time scale of a predetermined amount of the second solution in a predetermined amount of the first solution, at a predetermined temperature for the growth of nanosheets. The use of the obtained material is also presented.

Inverse temperature crystallization processes are provided to produce perovskite single crystals (PSCs), as well as surface passivation techniques for producing stabilizing the PSCs in the bulk region. Stable hybrid perovskite material include a bulk region comprising a single crystal perovskite material having a first bandgap and a smooth perovskite surface layer having a second bandgap greater than the first bandgap. Devices for detection and energy conversion are also contemplated, including for spectroscopic photon and elementary particle detection, such as radiation detectors. Crystallization chambers for forming the PSCs are also provided.

Inverse temperature crystallization processes are provided to produce perovskite single crystals (PSCs), as well as surface passivation techniques for producing stabilizing the PSCs in the bulk region. Stable hybrid perovskite material include a bulk region comprising a single crystal perovskite material having a first bandgap and a smooth perovskite surface layer having a second bandgap greater than the first bandgap. Devices for detection and energy conversion are also contemplated, including for spectroscopic photon and elementary particle detection, such as radiation detectors. Crystallization chambers for forming the PSCs are also provided.

This invention is a method for manufacturing a rectangular parallelepiped-shaped single crystal containing sodium niobate of a perovskite structure as the main component, and the method includes a process of heating a mixture 1 of bismuth sodium niobate which is formed from particles containing a plurality of crystals represented by General Formula (1): Bi.sub.2.5Na.sub.m1.5NbmO.sub.3m+3 (m is an integer of 2 or more) and in which an average value m.sub.a of the m values is larger than 6 and sodium containing alkali metal halide at 1200 C. or more and 1250 C. or less to obtain a rectangular parallelepiped-shaped single crystal containing sodium niobate as the main component.

This invention is a method for manufacturing a rectangular parallelepiped-shaped single crystal containing sodium niobate of a perovskite structure as the main component, and the method includes a process of heating a mixture 1 of bismuth sodium niobate which is formed from particles containing a plurality of crystals represented by General Formula (1): Bi.sub.2.5Na.sub.m1.5NbmO.sub.3m+3 (m is an integer of 2 or more) and in which an average value m.sub.a of the m values is larger than 6 and sodium containing alkali metal halide at 1200 C. or more and 1250 C. or less to obtain a rectangular parallelepiped-shaped single crystal containing sodium niobate as the main component.