Methods of sulfurizing metal containing particles in the absence of hydrogen are described. One method includes contacting a bed of metal containing particles with a gaseous stream comprising hydrogen sulfide and inert gas under reaction conditions sufficient to produce sulfided metal containing particles. The gaseous stream is introduced into a vertical reactor at an inlet positioned at the bottom portion of the reactor and any unreacted hydrogen sulfide and inert gas is removed at an outlet positioned above the inlet. The sulfided metal containing particles can be removed from the reactor and stored.

Methods of sulfurizing metal containing particles in the absence of hydrogen are described. One method includes contacting a bed of metal containing particles with a gaseous stream comprising hydrogen sulfide and inert gas under reaction conditions sufficient to produce sulfided metal containing particles. The gaseous stream is introduced into a vertical reactor at an inlet positioned at the bottom portion of the reactor and any unreacted hydrogen sulfide and inert gas is removed at an outlet positioned above the inlet. The sulfided metal containing particles can be removed from the reactor and stored.

Methods of sulfurizing metal containing particles in the absence of hydrogen are described. One method includes contacting a bed of metal containing particles with a gaseous stream comprising hydrogen sulfide and inert gas under reaction conditions sufficient to produce sulfided metal containing particles. The gaseous stream is introduced into a vertical reactor at an inlet positioned at the bottom portion of the reactor and any unreacted hydrogen sulfide and inert gas is removed at an outlet positioned above the inlet. The sulfided metal containing particles can be removed from the reactor and stored.

A process for preparing a copper sulfide of the formula Cu.sub.xS.sub.y, wherein the process comprises the following steps: (i) reacting an aqueous solution of a copper salt with a molar excess of a sulfiding agent so as to precipitate copper sulfide from the solution; (ii) isolating the copper sulfide precipitate from the reaction mixture; and (iii) drying the copper sulfide precipitate at a temperature of less than 100° C., wherein x and y are integer or non-integer values.

The present disclosure provides a Cu.sub.1.81S catalyst for synthesizing NH.sub.3 and a method for synthesizing NH.sub.3 using the same. According to the present disclosure, the Cu.sub.1.81S catalyst is provided in order to increase an efficiency of NH.sub.3 synthesis. A copper sulfide catalyst and the method for synthesizing NH.sub.3 via an electrochemical nitrogen reduction reaction (NRR) using the Cu.sub.1.81S catalyst are provided in order to reduce a limiting potential (UL) required for the NRR. In the NRR for the NH.sub.3 synthesis, it is provided the copper sulfide catalyst that can be used in any one of two different pathways for the NRR, and the method for synthesizing NH.sub.3 with higher activity of the NRR based thereon.

The present disclosure provides a Cu.sub.1.81S catalyst for synthesizing NH.sub.3 and a method for synthesizing NH.sub.3 using the same. According to the present disclosure, the Cu.sub.1.81S catalyst is provided in order to increase an efficiency of NH.sub.3 synthesis. A copper sulfide catalyst and the method for synthesizing NH.sub.3 via an electrochemical nitrogen reduction reaction (NRR) using the Cu.sub.1.81S catalyst are provided in order to reduce a limiting potential (UL) required for the NRR. In the NRR for the NH.sub.3 synthesis, it is provided the copper sulfide catalyst that can be used in any one of two different pathways for the NRR, and the method for synthesizing NH.sub.3 with higher activity of the NRR based thereon.

The present disclosure provides a method for preparing a vesicle, a hollow nanostructure, and a method for preparing the same. The preparation method of the vesicle includes: mixing and evenly stirring an aqueous solution of cetyl trimethyl ammonium bromide and an aqueous solution of tetraphenylethylene-bisphenol A; and allowing a stirred aqueous solution including cetyl trimethyl ammonium bromide and tetraphenylethylene-bisphenol A to stand for a first preset period to obtain an aggregate vesicle of cetyl trimethyl ammonium bromide and tetraphenylethylene-bisphenol A.

The present disclosure provides a method for preparing a vesicle, a hollow nanostructure, and a method for preparing the same. The preparation method of the vesicle includes: mixing and evenly stirring an aqueous solution of cetyl trimethyl ammonium bromide and an aqueous solution of tetraphenylethylene-bisphenol A; and allowing a stirred aqueous solution including cetyl trimethyl ammonium bromide and tetraphenylethylene-bisphenol A to stand for a first preset period to obtain an aggregate vesicle of cetyl trimethyl ammonium bromide and tetraphenylethylene-bisphenol A.

An exemplary method for producing a mixed metal chalcogenide under atmospheric pressure may include forming a reaction mixture by mixing a first metal chalcogenide and a second metal chalcogenide. An exemplary method may further include pouring a first layer of NaCl within a reactor, where an exemplary reactor may include a container and a cap. Pouring an exemplary first layer of NaCl within an exemplary reactor may include pouring an exemplary first layer of NaCl on an exemplary base end of an exemplary container of the exemplary reactor. An exemplary method may further include pouring an exemplary reaction mixture into an exemplary container on top of an exemplary first layer of NaCl, pouring a second layer of NaCl into an exemplary container on top of an exemplary reaction mixture, sealing an exemplary container by closing an exemplary cap and pouring molten NaCl on top of the exemplary cap, and heating an exemplary reactor at a predetermined temperature for a predetermined time.

An exemplary method for producing a mixed metal chalcogenide under atmospheric pressure may include forming a reaction mixture by mixing a first metal chalcogenide and a second metal chalcogenide. An exemplary method may further include pouring a first layer of NaCl within a reactor, where an exemplary reactor may include a container and a cap. Pouring an exemplary first layer of NaCl within an exemplary reactor may include pouring an exemplary first layer of NaCl on an exemplary base end of an exemplary container of the exemplary reactor. An exemplary method may further include pouring an exemplary reaction mixture into an exemplary container on top of an exemplary first layer of NaCl, pouring a second layer of NaCl into an exemplary container on top of an exemplary reaction mixture, sealing an exemplary container by closing an exemplary cap and pouring molten NaCl on top of the exemplary cap, and heating an exemplary reactor at a predetermined temperature for a predetermined time.