Laboratory of Digital Material Science

Methods for the synthesis of 2D h-BN and h-BNxOy using the boron oxide CVD technology, plasma-chemical synthesis from BCl3 and NH3, and the direct reaction of boric acid with ammonia have been studied. The efficiency of synthesis of nanocrystalline h-BN with a crystallite size of 6-10 nm in the reduction of boric acid in ammonia is shown. Abstract—The functionalization of the surface of boron nitride by hydrogen atoms in a hydrogen microwave plasma has been studied. It is shown that such treatment leads to an increase in the interplanar spacing along the c axis by 6–7%, which is associated with the hydrogenation of boron nitride. Abstract—The functionalization of the surface of boron nitride by chlorine and fluorine atoms during its high-temperature treatment with ammonium chloride and fluoride has been studied. A method for the functionalization of boron nitride in a hydrofluoric acid solution has been developed, which makes it possible to create structural defects on the surface of boron nitride.

The efficiency of the method of catalytic etching of h-BN powder particles with silver nanoparticles in order to form a defect structure is shown. As a result of the action of silver nanoparticles at a high temperature (950°C), pores are formed on the surface of the h-BN plate to a depth of several atomic layers. A similar heat treatment without Ag nanoparticles leads to the formation of pores only in the h-BN surface layer. The use of a powder consisting of defective h-BN particles as a substrate makes it possible to form transition metal nanoparticles with a size of less than 1 nm on their surface.

Catalysts Me/h-BNxOy (where Me = Cu, Ni, Pt) were synthesized and their catalytic activity was studied. It is shown that the replacement of nitrogen with oxygen in boron nitride leads to an increase in its catalytic activity. It has been established that the presence of oxygen centers leads to an increase in the catalytic activity of platinum, but inhibits the activity of copper and nickel, which is associated with a different redistribution of electron density in these metals.

The possibility of using phthalocyanine complexes as precursors of iron-based monatomic catalysts is shown. The deposition of iron phthalocyanine on the surface of h-BN leads to the formation of single atoms, while the oxidation of the organic framework does not significantly affect the metal content. The resulting Fe1/h-BN systems showed activity in the CO oxidation reaction with a conversion start temperature of 150°C.

To study the possibility of implantation of metals into the near-surface layers of boron nitride, modeling was carried out using the molecular dynamics method with the energies of metal atoms ~ 10^1 eV. The energy at which the fraction of metal atoms lying between the first and second h-BN layers is maximum was estimated. Then, within the framework of the electron density functional theory, a theoretical study of the catalytic activity of the h-BN system with an implanted metal atom was carried out. As an h-BN model with a defect, we considered a two-layer film with a boron vacancy located in the upper layer. The transition metal atom was placed under the vacancy between the layers on the assumption that such a defect was formed as a result of irradiation of h-BN with metal ions. The change in the total energy of the system in the density functional theory during the dissociative adsorption of methane on a defect is used as the activity index of the described center. Of all metals, the atoms of the end of the periods of transition metals, starting with Ni, are active. In this case, only for Cu and Ag, a significant magnetization of the edge nitrogen atoms of the vacancy defect was observed. Obviously, this circumstance plays a decisive role in the activity of this center in the radical mechanism of hydrogen abstraction from methane.