Methods for producing ethylene using nanowires as heterogeneous catalysts are provided. The method includes, for example, an oxidative coupling of methane catalyzed by nanowires to provide ethylene.

Provided are a scroll preparing method using a two-dimensional material and a scroll prepared thereby. The scroll preparing method comprises preparing a two-dimensional material. The two-dimensional material is scrolled by providing an amphiphilic substance having a hydrophilic portion and a hydrophobic portion on the two-dimensional material. As a result, a scroll composite including the amphiphilic substance disposed inside a scroll structure is formed.

Provided are a scroll preparing method using a two-dimensional material and a scroll prepared thereby. The scroll preparing method comprises preparing a two-dimensional material. The two-dimensional material is scrolled by providing an amphiphilic substance having a hydrophilic portion and a hydrophobic portion on the two-dimensional material. As a result, a scroll composite including the amphiphilic substance disposed inside a scroll structure is formed.

The present invention relates to a method for preparing uniform metal oxide nanoparticles. According to the preparation method of the present invention, it is possible to maintain the temperature and pressure inside the reactor in a stable and constant manner by removing water generated in the reaction step for forming metal oxide nanoparticles. Thus, the uniformity of nanoparticles formed is increased, and the reproducibility between batches can be increased even in a repeated process and and a large-scale reaction. Therefore, the preparation method of the present invention can be used to synthesize uniform nanoparticles reproducibly in large quantities.

A process for producing black powder oxygen carriers for use in a chemical looping combustion unit includes the steps of: (a) removing and collecting the black powder waste material that was formed in a gas pipeline; (b) pre-treating the collected black powder to adjust its spherical shape to avoid attrition and fines production; and (c) activating the black powder to increase its reactivity rate and produce the black powder oxygen carrier that is suitable for use in the chemical looping combustion process as an oxygen carrier.

Disclosed herein are multifunctional nanoparticle compositions. The compositions can be useful for the treatment of cancer by enhancing the anti-tumor effectiveness of radiation directed to a tissue, cell or a tumor and the methods of use thereof. The multifunctional nanoparticle composition comprises a metal oxide nanoparticle core; a functional coating on the surface of the metal oxide nanoparticle core; and a matrix carrier in which the coated nanoparticle is embedded.

This invention provides a membrane electrode material and its preparation method, as well as the application of the material into lithium extraction by adsorption-electrochemical coupling method. The membrane electrode material is described as MnO@C. The preparation steps are as follows: LiMn.sub.2O.sub.4 is firstly obtained by calcining lithium carbonate and manganese carbonate, which is then dispersed in hydrochloric acid solution. After stirring and separating, the solid products are dried to obtain λ-MnO.sub.2. The λMnO.sub.2 is added to the raw material of Mn-MOF-74, and then the Mn-MOF-74 coated λ-MnO.sub.2 can be obtained by hydrothermal reaction. By further calcining Mn-MOF-74 coated λ-MnO.sub.2 in nitrogen atmosphere, the membrane capacitor/electrode material can be obtained as MnO@C. The material is fabricated into an adsorption film electrode plate and assembled into an adsorption-electrochemical coupling lithium extraction device. The pure lithium solution can be obtained in the recovery pool through the combined lithium extraction and lithium recovery process. In this invention, the thickness of the carbon coating layer in the electrode material is adjustable. Adsorption-electrochemical coupling technology takes the advantages of both adsorption and electrochemical lithium intercalation, which can extract and recover lithium resources with high capacity. Thus, this invention not only achieves high-efficiency separation of lithium resources, but also opens up a new way for the extraction of lithium resources.

This invention provides a membrane electrode material and its preparation method, as well as the application of the material into lithium extraction by adsorption-electrochemical coupling method. The membrane electrode material is described as MnO@C. The preparation steps are as follows: LiMn.sub.2O.sub.4 is firstly obtained by calcining lithium carbonate and manganese carbonate, which is then dispersed in hydrochloric acid solution. After stirring and separating, the solid products are dried to obtain λ-MnO.sub.2. The λMnO.sub.2 is added to the raw material of Mn-MOF-74, and then the Mn-MOF-74 coated λ-MnO.sub.2 can be obtained by hydrothermal reaction. By further calcining Mn-MOF-74 coated λ-MnO.sub.2 in nitrogen atmosphere, the membrane capacitor/electrode material can be obtained as MnO@C. The material is fabricated into an adsorption film electrode plate and assembled into an adsorption-electrochemical coupling lithium extraction device. The pure lithium solution can be obtained in the recovery pool through the combined lithium extraction and lithium recovery process. In this invention, the thickness of the carbon coating layer in the electrode material is adjustable. Adsorption-electrochemical coupling technology takes the advantages of both adsorption and electrochemical lithium intercalation, which can extract and recover lithium resources with high capacity. Thus, this invention not only achieves high-efficiency separation of lithium resources, but also opens up a new way for the extraction of lithium resources.

A method for making a catalyst for ozone decomposition includes: adding a reducing agent into a water solution of a permanganate salt to obtain a first reaction liquid, and heating the first reaction liquid under continuous stirring to form a birnessite-type manganese dioxide; and adding the birnessite-type manganese dioxide into a water solution of an ammonium salt to obtain a second reaction liquid, and heating the second reaction liquid under continuous stirring to form the catalyst.

A method of increasing a solubility of a manganese oxide includes contacting the manganese oxide with an acid component in the presence of a dissolution accelerator that includes at least one of hydrazine, a hydrazine derivative, or a hydrazide. Also disclosed is a drilling fluid containing a carrier; MnO.sub.2; and at least one of a viscosifier, a rheology modifier, a dispersant, a weighting agent, a defoamer, a fluid loss agent, bentonite, or a lubricant.