Electrodialyzer and electrodialysis system for co2 capture from ocean water

What is claimed is: 1 . An electrodialyzer, comprising: one or more multi-compartment cells, each of the cells including: a saltwater compartment; a base compartment receiving a base solution stream; and a bipolar membrane (BPM) separating the saltwater compartment and base compartment; a catholyte compartment; a first monovalent cation exchange membrane (M-CEM) separating the catholyte compartment and the saltwater compartment of one of the multi-compartment cells; a cathode contacting the catholyte compartment; an anolyte compartment; a second M-CEM separating the anolyte compartment and the base compartment of one of the multi-compartment cells; an anode contacting the anolyte compartment; and one or more intermediate monovalent cation exchange membranes (M-CEMs)separating the multi-compartment cells, if there is more than one multi-compartment cell in the electrodialyzer. 2 . The electrodialyzer of claim 1 , wherein the electrodialyzer is used to remove carbon dioxide from ocean water. 3 . The electrodialyzer of claim 1 , wherein the saltwater compartment receives a stream of filtered ocean water. 4 . The electrodialyzer of claim 1 , wherein the base stream is NaOH. 5 . The electrodialyzer of claim 1 , wherein the catholyte compartment and the anolyte compartment each receive a recirculated electrolyte solution, respectively. 6 . The electrodialyzer of claim 5 , wherein the electrolyte solution includes a one-electron, electrochemically reversible redox couple. 7 . The electrodialyzer of claim 6 , wherein the one-electron, electrochemically reversible redox couple is selected from the group consisting of Na 3 /Na 4 —[Fe(CN) 6 ] and K 3 /K 4 —[Fe(CN) 6 ]. 8 . The electrodialyzer of claim 1 , wherein each of the intermediate CEMs is configured to allow the transfer of monovalent cations from the saltwater compartment to the base compartment of an adjacent cell, while rejecting the transfer of anions and multivalent cations from the saltwater compartment to the base compartment in the adjacent cell. 9 . The electrodialyzer of claim 1 , wherein the BPM generates proton (H + ) and hydroxide ion (OH − ) fluxes via water dissociation reactions at a BPM interface, where the proton flux is provided to the saltwater compartment so as to convert an input saltwater stream to the saltwater compartment into an output stream of acidified saltwater, and the hydroxide ion is provided to the base compartment to increase the base concentration of the base stream received by the base compartment. 10 . An electrodialyzer, comprising: one or more multi-compartment cells, each of the cells including: a first compartment; a second compartment; an anion exchange membrane (AEM) separating the first compartment and the second compartment; a third compartment; and a bipolar membrane (BPM) separating the second compartment and the third compartment; a catholyte compartment; a first monovalent cation exchange membrane (M-CEM) separating the catholyte compartment and the first compartment of one of the multi-compartment cells; a cathode contacting the catholyte compartment; an anolyte compartment; a second M-CEM separating the anolyte compartment and the third compartment of one of the multi-compartment cells; an anode contacting the anolyte compartment; and one or more intermediate monovalent cation exchange membranes (M-CEMs)separating the multi-compartment cells, if there is more than one multi-compartment cell in the electrodialyzer. 11 . The electrodialyzer of claim 10 , wherein an output stream of the second compartment is input to the first compartment. 12 . The electrodialyzer of claim 10 , wherein the third compartment receives a base stream. 13 . The electrodialyzer of claim 10 , wherein the second compartment receives a stream of filtered ocean water. 14 . The electrodialyzer of claim 10 , wherein the first, second, and third compartments each receive a respective stream of filtered ocean water. 15 . The electrodialyzer of claim 10 , wherein the AEM allows the passage of anions from the first compartment to the second compartment and rejects the passage of cations between the first compartment and the second compartment. 16 . The electrodialyzer of claim 10 , wherein the catholyte compartment and the anolyte compartment each receive a recirculated electrolyte solution, respectively. 17 . The electrodialyzer of claim 16 , wherein the electrolyte solution includes a one-electron, electrochemically reversible redox couple. 18 . The electrodialyzer of claim 17 , wherein the one-electron, electrochemically reversible redox couple is selected from the group consisting of Na 3 /Na 4 —[Fe(CN) 6 ] and K 3 /K 4 —[Fe(CN) 6 ]. 19 . The electrodialyzer of claim 10 , wherein the BPM generates proton (H + ) and hydroxide ion (OH − ) fluxes via water dissociation reactions at the BPM interface, where the proton flux is provided to the second compartment so as to convert an input saltwater stream to the second compartment into an output stream of acidified saltwater, and the hydroxide ion flux is provided to the third compartment to increase the base concentration of a stream received by the third compartment. 20 . The electrodialyzer of claim 10 , wherein each of the intermediate CEMs is configured to allow the transfer of monovalent cations from the first compartment to the third compartment of an adjacent cell, while rejecting the transfer of anions and multivalent cations from the first compartment to the third compartment in the adjacent cell.