Aqueous energy storage systems with desalination capabilities

What is claimed is: 1. A method that couples the ion extraction and recovery with energy storage and release using an aqueous electrolyte solution comprising: sodium ions or lithium ions; and chloride ions, the method comprising: (a) charging a first electrochemical cell comprising: the aqueous electrolyte solution; a chloride storage anode comprising a dechlorinated chloride storage material; and a sodium storage cathode comprising a first desodiated sodium storage material or a lithium storage cathode comprising a first delithiated lithium storage material, wherein the charging results in: the removal of the chloride ions and the sodium ions from the aqueous electrolyte solution or the removal of the chloride ions and the lithium ions from the aqueous electrolyte solution; the conversion of the dechlorinated chloride storage material into a chlorinated chloride storage material; and the conversion of the first desodiated sodium storage material into a first sodiated sodium storage material or the conversion of the first delithiated lithium storage material into a first lithiated lithium storage material; (b) charging a second electrochemical cell comprising: an ion-recovery electrolyte solution; a sodium storage anode comprising a second sodiated sodium storage material or a lithium storage anode comprising a second lithiated lithium storage material; and a chlorinated chloride storage cathode comprising the chlorinated chloride storage material, wherein the charging results in: the release of chloride ions and sodium ions into the ion-recovery electrolyte solution or the release of chloride ions and lithium ions into the ion-recovery electrolyte solution; the conversion of the chlorinated chloride storage material into the dechlorinated chloride storage material; and the conversion of the second sodiated sodium storage material into a second desodiated sodium storage material or the conversion of the second lithiated lithium storage material into a second delithiated lithium storage material; and (c) discharging a discharging electrochemical cell comprising: a discharging electrolyte solution; a sodium storage anode comprising the first sodiated sodium storage material or a lithium storage anode comprising the first lithiated lithium storage material; and a sodium storage cathode comprising the second desodiated sodium storage material or a lithium storage cathode comprising the second delithiated lithium storage material, wherein the discharging generates an output voltage. 2. The method of claim 1 , wherein charging step (a), charging step (b), and discharging step (c) are carried out in a single electrochemical cell compartment. 3. The method of claim 1 , wherein the first electrochemical cell is a desalination cell that comprises the sodium storage cathode comprising the first desodiated sodium storage material and the second electrochemical cell is a salination cell that comprises the sodium storage anode comprising the second sodiated sodium storage material. 4. The method of claim 3 , wherein the aqueous electrolyte solution comprises water from a natural body of water. 5. The method of claim 4 , wherein the aqueous electrolyte solution comprises seawater. 6. The method of claim 4 , wherein the first desodiated sodium storage material is NaTi 2 (PO 4 ) 3 and the second sodiated sodium storage material is a sodiated form of nickel hexacyanoferrate. 7. The method of claim 6 , wherein the dechlorinated chloride storage material comprises bismuth. 8. The method of claim 1 , wherein the first electrochemical cell is a dilithiation cell that comprises the lithium storage cathode comprising the first delithiated lithium storage material and the second electrochemical cell is a lithiation cell that comprises the lithium storage anode comprising the second lithiated lithium storage material. 9. The method of claim 8 , wherein the first aqueous electrolyte solution comprises water from a geothermal brine.