Redox desalination system for clean water production and energy storage

What is claimed is: 1. A system for the treatment of water, the system comprising at least an electrochemical desalination battery (EDB) unit comprising: at least one water chamber configured to hold water to be treated; at least one negative-ion redox electrode comprising a solution of an electrolyte material selected from cerium chloride, germanium chloride, vanadium chloride, europium chloride, and ferrous chloride, and capable of accepting, and having a reversible redox reaction with, at least one negative ion in the water; at least one positive-ion redox electrode capable of accepting, and having a reversible redox reaction with, at least one positive ion in the water, wherein the positive-ion redox electrode is immersed in the water chamber or separated from the water chamber by an optional porous separator; and an ion exchange membrane separating the at least one negative-ion redox electrode from the water chamber. 2. The system of claim 1 , further comprising a capacitive deionization (CD) unit connected to the EDB unit via a water port and comprising a first electrode, a second electrode, and a water flow region located between the first and second electrodes. 3. The system of claim 2 , wherein: the EDB unit is configured to operate alternately in a desalination mode and in a salination mode; ions are released from the at least one negative-ion redox electrode and the at least one positive-ion redox electrode, and energy is stored in the EDB unit in the salination mode; and the EDB unit desalinates water therein while releasing stored energy as output power employing the at least one negative-ion redox electrode as a positive output electrode and the at least one positive-ion redox electrode as a negative output electrode in the desalination mode. 4. The system of claim 3 , wherein the CD unit performs a desalination process while the EDB unit operates in the desalination mode, and performs a salination process while the EDB unit operates in the salination mode. 5. The system of claim 3 , wherein at least a fraction of the output power generated from the EDB unit is applied across the first and second electrodes of the CD unit during the desalination mode. 6. The system of claim 3 , further comprising a water flow control device to induce flow of water in different directions between the desalination mode and the salination mode, wherein: the water flow control device induces water to flow from the EDB unit to the CD unit during the desalination mode; and the water flow control device induces water to flow from the CD unit to the EDB unit during the salination mode. 7. The system of claim 3 , wherein a combination of the EDB unit and the CD unit is configured to generate water having a total dissolved solid (TDS) count not greater than about 500 mg per liter in the desalination mode. 8. The system of claim 1 , wherein a separation distance between the anion exchange membrane and the at least one positive-ion redox electrode decreases along a direction of water flow during the desalination mode. 9. The system of claim 1 , wherein the cathode comprises a compound selected from manganese oxide, copper hexacyanoferrate, prussian blue derivatives, vanadium pentoxide, and sodium ferricyanide. 10. The system of claim 1 , further comprising: a set of electrical switches configured to switch electrical connections for the at least one negative-ion redox electrode and the at least one positive-ion redox electrode between a desalination mode and a salination mode during operation of the EDB unit, wherein: the set of electrical switches is configured to connect the at least one negative-ion redox electrode to a positive output voltage node of a power supply unit and connects the at least one positive-ion redox electrode to a negative output voltage node of the power supply unit, respectively, in the salination mode in which ions are released from the at least one negative-ion redox electrode and the at least one positive-ion redox electrode and energy is stored in the EDB unit; and the set of electrical switches is configured to connect the at least one negative-ion redox electrode to a positive electrode of an electrical load and connects the at least one positive-ion redox electrode to a negative electrode of the electrical load, respectively, in the desalination mode in which the EDB unit desalinates water therein while releasing stored energy as output power employing the at least one negative-ion redox electrode as a positive output electrode and the at least one positive-ion redox electrode as a negative output electrode. 11. The system of claim 10 , wherein: the electrical load comprises a power grid to which the EDB unit supplies electrical power through an inverter; and the set of electrical switches constitutes components of an operational mode control device that is configured to select between the desalination mode and the salination mode based on presence or absence of power demand from the power grid. 12. The system of claim 1 , wherein water in the EDB unit is configured to reduce a total dissolved salt count in processed water by at least about 50% during the desalination mode, and is configured to at least double a total dissolved salt count in processed water during the salination mode. 13. A method of desalinating water, comprising: providing an electrochemical desalination battery (EDB) unit comprising: at least one water chamber configured to hold water to be treated; at least one negative-ion redox electrode comprising a solution of an electrolyte material selected from cerium chloride, germanium chloride, vanadium chloride, europium chloride, and ferrous chloride, and capable of accepting, and having a reversible redox reaction with, at least one negative ion in the water; at least one positive-ion redox electrode capable of accepting, and having a reversible redox reaction with, at least one positive ion in the water, wherein the positive-ion redox electrode is immersed in the water chamber or separated from the water chamber by an optional porous separator; and an ion exchange membrane separating the at least one negative-ion redox electrode from the water chamber; transporting water having a first salinity into the at least one water chamber; desalinating the water having the first salinity to provide water having a second salinity that is lower than the first salinity employing the EDB unit; and removing the water having the second salinity from the EDB unit. 14. The method of claim 13 , further comprising: transporting the water having the second salinity into a capacitive deionization (CD) unit comprising a first electrode, a second electrode, and a water flow region located between the first and second electrodes; and desalinating the water transported into the CD unit to provide water having a third salinity that is lower than the second salinity. 15. The method of claim 14 , further comprising inducing flow of water in different directions between a desalination mode and the salination mode employing a water flow control device, wherein: the water flow control device induces water to flow from the EDB unit to the CD unit during the desalination mode; and the water flow control device induces water to flow from the CD unit to the EDB unit during the salination mode. 16. The method of claim 13 , further comprising: connecting the at least one negative-ion redox electrode to a positive output voltage node of a power supply unit and connecting the at least one positive-ion redox electrode to a negative output voltage node of