Electrosynthesis of oxirane can include contacting a halide electrolyte with an anode and cathode respectively located in anodic and cathodic compartments; supplying olefin reactants into the electrolyte in the anodic compartment, such that the anode generates ethylene chlorohydrin; withdrawing a loaded anodic solution comprising ethylene halohydrin from the anodic compartment, and a loaded cathodic solution comprising OH.sup.- ions from the cathodic compartment; and mixing the loaded anodic solution with the loaded cathodic solution under conditions to react ethylene halohydrin with OH- to produce oxirane. The electrocatalyst can include iridium oxide on a titanium substrate, with the iridium oxide provided as nanoparticles on a titanium mesh, and the electrolyte can be aqueous KCl. The electrocatalyst can define an extended heterogenous:homogenous interface with halide ions acting as a reservoir for positive charges, thereby storing and redistributing positive charges to promote selective generation of ethylene halohydrins.

Disclosed herein are methods and systems that relate to an on-line monitoring of a process/system by controlling rate of oxidation of metal ions at an anode in an anode electrolyte of an electrochemical process and controlling rate of reduction of the metal ions in a catalysis process to achieve steady state.

A method of making alkenes and/or epoxides from alkanes and hydroxy-alkanes, respectively. In a reactor having an anode and a cathode separated by an ion exchange membrane, and containing a solution comprising water, halogen ions, and an alkane and/or a hydroxy-alkane, apply a potential across the anode and the cathode such that a halogenated intermediate is produced at the anode as an anolyte and hydroxyl ions are produced at the cathode as a catholyte; and combining the anolyte and the catholyte to yield an alkene and/or an epoxide.

Provided herein are methods of fluorinating organic compounds. The electrochemical fluorination and radiofluorination of organic molecules using the cation pool technique is described, where the 18F and/or 19F-fluorine ions are added after the process of electrochemical oxidation, i.e., after formation of a carbocationic organic compound (i.e., a compound having a carbon atom with a positive charge).

Disclosed in the present invention are methods for the electrochemical generation of aqueous organic haloamine solutions from precursor solutions comprising at least one halide-containing salt, at least one organic amine component, and an acid additive. The described method allows for the production of aqueous organic haloamine solutions with compositions ranging from a single organic haloamine component to multiple organic haloamine components and multiple free halogen components and solutions with desired pH values.

Disclosed in the present invention are methods for the electrochemical generation of aqueous organic haloamine solutions from precursor solutions comprising at least one halide-containing salt, at least one organic amine component, and an acid additive. The described method allows for the production of aqueous organic haloamine solutions with compositions ranging from a single organic haloamine component to multiple organic haloamine components and multiple free halogen components and solutions with desired pH values.

There are provided methods and systems for an electrochemical cell including an anode and a cathode where the anode is contacted with a metal ion that converts the metal ion from a lower oxidation state to a higher oxidation state. The metal ion in the higher oxidation state is reacted with hydrogen gas, an unsaturated hydrocarbon, and/or a saturated hydrocarbon to form products.

There are provided methods and systems for an electrochemical cell including an anode and a cathode where the anode is contacted with a metal ion that converts the metal ion from a lower oxidation state to a higher oxidation state. The metal ion in the higher oxidation state is reacted with hydrogen gas, an unsaturated hydrocarbon, and/or a saturated hydrocarbon to form products.

Disclosed herein are methods and systems that relate to various configurations of electrochemical, bromination, oxybromination, bromine oxidation, hydrolysis, neutralization, and epoxidation reactions to form propylene bromohydrin, propanal, and propylene oxide or to form bromoethanol, bromoacetaldehyde, and ethylene oxide.

Disclosed herein are methods and systems that relate to various configurations of electrochemical, bromination, oxybromination, bromine oxidation, hydrolysis, neutralization, and epoxidation reactions to form propylene bromohydrin, propanal, and propylene oxide or to form bromoethanol, bromoacetaldehyde, and ethylene oxide.