Enhanced electrosynthesis of oxiranes

We claim: 1 . An electrocatalyst for selective anodic oxidation of an olefin reactant to produce ethylene halohydrin in a halide ion based electrolyte, the electrocatalyst comprising iridium oxide loaded with a period-6 metal oxide and provided on a substrate. 2 . The electrocatalyst of claim 1 , wherein the period-6 metal oxide comprises barium oxide, lanthanum oxide, cerium oxide, or bismuth oxide or a combination thereof. 3 . The electrocatalyst of claim 1 , wherein the period-6 metal oxide is barium oxide. 4 . The electrocatalyst of claim 1 , wherein the substrate comprises metal, carbon, or porous ceramic. 5 . The electrocatalyst of claim 1 , wherein the substrate comprises titanium. 6 . The electrocatalyst of claim 1 , wherein the substrate is in the form of a mesh, felt, foam, or cloth. 7 . The electrocatalyst of claim 1 , wherein the iridium oxide is provided as nanoparticles on the metal substrate. 8 . The electrocatalyst of claim 1 , wherein the substrate is in the form of a network of filaments defining openings, and the iridium oxide and period-6 metal oxide is deposited on the filaments and also forms a catalytic web extending across the openings 9 . The electrocatalyst of claim 1 , wherein the halide ion comprises Cl and the halide ion based electrolyte is an aqueous KCl electrolyte. 10 . The electrocatalyst of claim 1 , wherein the period-6 metal oxide has a loading between 1 wt % and 4 wt % with respect to the iridium oxide. 11 . A method of manufacturing the electrocatalyst as defined in claim 1 , comprising depositing iridium oxide onto a substrate to form an iridium oxide layer and loading a period-6 metal oxide with respect to the iridium oxide layer to form a loaded catalytic material. 12 . The method of claim 11 , wherein the loading is performed to provide between 0.5 wt % and 5 wt % loaded period-6 metal oxide with respect to the iridium oxide layer, and further comprising pre-treating the substrate prior to depositing the iridium oxide thereon, and wherein the pre-treating comprises etching. 13 . An electrocatalyst for selective anodic oxidation of an olefin reactant to produce ethylene halohydrin in a halide ion based electrolyte, the electrocatalyst comprising a primary metal catalyst associated with an HO-halide-cleavage inhibitor and provided on a substrate. 14 . The electrocatalyst of claim 13 , wherein the HO-halide-cleavage inhibitor comprises a period-6 metal oxide. 15 . The electrocatalyst of claim 13 , wherein the primary metal catalyst comprises iridium oxide, cobalt oxide, platinum, platinum oxide, palladium or palladium oxide. 16 . An electrochemical process for producing oxirane from olefin reactants, comprising: contacting a halide based electrolyte with an anode located in an anodic compartment, the anode comprising the electrocatalyst as defined in claim 13 ; generating a source of OH − at a cathode in a cathodic compartment; contacting olefin reactants with the electrolyte to generate ethylene halohydrin; and contacting the ethylene halohydrin with a solution comprising OH − ions to form oxirane. 17 . An electrochemical process for producing oxirane from olefin reactants, comprising: contacting a chloride based electrolyte with an anode located in an anodic compartment, to generate hypochlorous acid; contacting a catholyte with a cathode located in a cathodic compartment under oxygen reduction reaction (ORR) conditions; contacting olefin reactants with at least a portion of the hypochlorous acid to generate ethylene chlorohydrin; and converting at least a portion of the ethylene chlorohydrin to oxirane. 18 . The process of claim 17 , further comprising withdrawing the chloride based electrolyte from the anodic compartment and contacting the electrolyte with the olefin reactants to form an anodic solution comprising the ethylene chlorohydrin; and withdrawing a loaded cathodic solution comprising OH − ions from the cathodic compartment and mixing the anodic solution with the loaded cathodic solution to react the ethylene chlorohydrin with the OH − to produce the oxirane. 19 . An electrochemical process for producing oxirane from olefin reactants, comprising: in a first electrochemical subsystem contacting CO 2 with an electroreduction catalyst to convert the CO 2 into olefins and contacting a first anolyte with an oxidation electrocatalyst, thereby generating olefin reactants; in a second electrochemical subsystem, contacting a halide based electrolyte with an electrocatalyst to produce HOX species, wherein X is a halide, and contacting a catholyte with a cathodic catalyst; contacting at least a portion of the halide based electrolyte comprising the HOX species with at least a portion of the olefin reactants to form ethylene halohydrin; and contacting the ethylene halohydrin with OH − ions to form oxirane. 20 . The process of claim 19 , wherein the first anolyte comprises water and the oxidation electrocatalyst causes generation of oxygen; the first anolyte is circulated through a first anodic compartment that accommodates the oxidation electrocatalyst; the electroreduction catalyst is copper based and is provided on a PTFE gas diffusion membrane; the oxidation electrocatalyst comprises IrO 2 ; the oxidation electrocatalyst and the electroreduction catalyst are separated by and in contact with an anion exchange membrane; the second electrochemical subsystem comprises an air conduit for passage of air for contacting a first side of the cathodic catalyst, and a cathodic compartment receiving the catholyte and allowing contact thereof with a second side of the cathodic catalyst; the catholyte comprises water and is circulated through the cathodic compartment; the catholyte withdrawn from the cathodic compartment provides a source of the OH − ions used to contact the ethylene halohydrin to form the oxirane; a first portion of the catholyte withdrawn from the cathodic compartment is flowed for addition to the ethylene halohydrin, and a second portion is recirculated through the cathodic compartment; the halide based electrolyte comprising the HOX species is removed from an anodic compartment of the second electrochemical subsystem and supplied into a vessel along with at least a portion of the olefin reactants from the first electrochemical subsystem to form an anodic electrolyte mixture; a first portion of the anodic electrolyte mixture is supplied from the vessel into the anodic compartment as at least part of the halide based electrolyte; a second portion of the anodic electrolyte mixture is removed from the vessel and contacted with the OH − ions to form the oxirane; and the electrocatalyst of the second electrochemical subsystem comprises iridium oxide, cobalt oxide, platinum, platinum oxide, palladium or palladium oxide.