A preparation method for Ni and Mn bimetallic electrocatalyst and its application in small molecule electrooxidation are provided. The method includes the following steps: cleaning a matrix to remove a surface oxide layer; dissolving nickel salt, manganese salt, terephthalic acid, salicylic acid, and urea into a mixed solution of ethanol, DMF, and water and transferring to a hydrothermal reaction kettle together with the treated matrix for a hydrothermal reaction; then, obtaining a NiMn-MOF/NF precursor by cooling, cleaning, and drying. Dissolving and stirring sodium borohydride and selenium powder and transferring the above solution to the hydrothermal reaction kettle for hydrothermal selenization reaction with NiMn-MOF/NF; then, obtaining a self-supporting NiMn-MOF-Se catalyst with uniform nanosheet structure by cooling and cleaning. The catalyst synthesis method is simple and controllable, with low cost, uniform catalyst morphology, and good conductivity, it can be directly used as an electrode.

A catalyst for improving emissions and fuel efficiency in combustion chambers may include aluminum chloride, cerium (III) chloride, deionized water, propylene glycol, lithium chloride, chloroplatinic acid, rhodium chloride, perrhenic acid, and a pH adjuster, such as lithium hydroxide or hydrochloric acid reagent. A method of improving emissions and fuel efficiency in combustion chambers while simultaneously enhancing combustion of hydrocarbons may include introducing the catalyst via a vaporous transport into the flame zone of a combustion chamber.