39results about How to "Many surface defects" patented technology

The invention discloses a preparation method of a water electrolysis oxygen evolution non-noble metal catalyst. The preparation method includes the steps that firstly, pyridine monomers I containing acyl or pyridine monomers I containing amidogen are added into a solvent, then monomers II containing amidogen or monomers II containing acyl and a catalyst are added in, and synthesis is performed by rising temperature; secondly, metal salt is added in, metal ions are added in for complexing, wherein according to the molar weight of the metal ions, the molar ratio of the metal ions to the pyridine monomers I containing acyl or the pyridine monomers I containing amidogen is 1-2: 1-2; thirdly, the solvent is removed, and the remaining obtained solid substances are dried for 8-24 hours at 80-100 DEG C; fourthly, mixed gas is introduced for heating, and primary heat treatment is performed; and fifthly, aftertreatment then is performed after temperature lowering, and the product is obtained. Active metal atoms of the non-noble metal catalyst prepared through the preparation method are evenly dispersed in a catalyst material, no metal-metal bonds exist, the metal utilizing rate reaches up to 100%, and the non-noble metal catalyst has the beneficial effects of being good in electric conduction performance, high in specific surface area, few in surface defect and the like.

The invention discloses hydrogel with microcurrent and a medicine slow-release function and a preparation method and application. The preparation method comprises the following steps: carrying out reaction on a medicine and a carbon quantum dot so as to obtain a medicine-carried carbon quantum dot; uniformly mixing a sodium alginate solution, a sodium carboxymethyl cellulose solution, a power generation substance, the medicine-carried carbon quantum dot and anhydrous calcium carbonate powder so as to obtain mixed liquid A; adding glucose lactone into the mixed liquid A, uniformly stirring, performing ultrasonic defoaming, leveling, and drying, thereby obtaining the hydrogel with the microcurrent and the medicine slow-release function. The hydrogel has the advantages of excellent mechanical property, very good medicine slow-release property, very good heal promotion effects, very good swelling property, very good biological security and large market application prospect.

The present invention relates to a preparation method of HMX / ANPyO eutectic under the confinement doping condition of a two-dimensional material. Triaminoguanidine nitrate (TAGN) is mixed with dimethyl sulfoxide (DMSO), and then HMX and ANPyO are added and waited for Dissolve completely, add glyoxal to obtain a two-dimensional conjugated structure material; grow HMX / ANPyO on this two-dimensional conjugated structure, and obtain HMX / ANPyO co-crystal under confined doping conditions. The method of the invention is simpler, the final material structure and performance can be precisely controlled through reaction conditions and doping amount, the product yield is high, the cost of raw materials used is low, and industrial production is easy to realize. Secondly, under the confinement doping conditions of two-dimensional materials, its crystal stiffness and molecular order packing density are improved, thereby improving its detonation performance. Finally, under the confinement doping conditions of 2D materials, HMX and ANPyO can form co-crystals in any ratio, and the experimental conditions are easy to control.

The invention provides a catalyst for preparing CO by a reverse water gas shift method and a preparation method thereof, the catalyst expression is Pd-I / CeO 2 , wherein the mass percentage of Pd is 1-4wt.%, and the surface I / Pd molar ratio is 0.2-0.5. The present invention finely controls the preparation process of the catalyst, first expands the crystal lattice of cerium oxide through chlorine atoms, then dopes iodine atoms into the catalyst, and finally removes the excessively doped iodine element through the oxidation-reduction cycle process to obtain a catalyst with a specific structure and performance catalysts. The catalyst is used in the reaction of preparing CO by the reverse water gas shift method, the conversion rate of CO in the reaction zone of 400-600 DEG C is 26.2-50%, and the selectivity of CO is 97-99%. Significantly higher than existing catalysts.