Systems and Methods for Electrochemical Hydrogen Looping

What is claimed is: 1 . An electrochemical system comprising: a cathode with a first side contacting a cathode gas chamber and a second side contacting a catholyte; and an anode with a first side contacting an anode gas chamber and a second side contacting an anolyte, wherein the catholyte and the anolyte is separated by a separator; wherein the cathode is configured to catalyze a hydrogen evolution reaction and produce hydrogen gas and a basic stream with a pH less than or equal to 13 and greater than or equal to 7, and the anode is configured to catalyze a hydrogen oxidation reaction and produce an acidic stream with a pH greater than or equal to 1 and less than or equal to 7; and wherein the cathode gas chamber connects with the anode gas chamber via a flow channel such that the hydrogen gas flows from the anode to the cathode. 2 . The electrochemical system of claim 1 , wherein the cathode and the anode each comprises a gas diffusion electrode that separates a gas phase and a liquid phase. 3 . The electrochemical system of claim 1 , wherein the second side of the cathode and the second side of the anode each comprises a layer configured to be a barrier to prevent a gas phase and a liquid phase from mixing; wherein the layer is selected from the group consisting of: a polymer layer, a ceramic layer, a layer with a positive electrical charge, and a layer with a negative electrical charge. 4 . The electrochemical system of claim 3 , wherein the layer comprises an ionomer selected from the group consisting of a Nafion® ionomer, a Nafion® D520 ionomer, a Sustainion® ionomer, and a Versogen® PiperION-A5 ionomer. 5 . The electrochemical system of claim 3 , wherein the layer prevents buildup of precipitates on the electrodes when performing polarity switch to the cathode and the anode. 6 . The electrochemical system of claim 3 , wherein the layer prevents bubble formation on the cathode and the anode. 7 . The electrochemical system of claim 1 , further comprises current collectors connected to the cathode and the anode for connecting the cathode and the anode to an external circuit. 8 . The electrochemical system of claim 1 , wherein the catholyte and the anolyte comprise sodium ions and chloride ions. 9 . The electrochemical system of claim 1 , wherein ionic concentrations of the catholyte and the anolyte are higher than proton and hydroxide ion concentrations such that neutralization of the acidic and basic streams is minimized. 10 . The electrochemical system of claim 1 , wherein the separator comprises a filter paper, a qualitative grade filter paper, a quantitative grade filter paper, a glass fiber filter, a quartz fiber filter, a chromatography filter paper, a coffee filter paper, a tea filter paper, a ceramic membrane, or a sodium superionic conductor membrane. 11 . The electrochemical system of claim 1 , wherein the system is configured to achieve a current density less than or equal to 500 mA/cm 2 . 12 . The electrochemical system of claim 1 , wherein the system has a configuration selected from the group consisting of: an H cell, a cell stack, a flow cell, and a flow stack. 13 . The electrochemical system of claim 1 , wherein the basic stream has a pH greater than 12 and the acidic stream has a pH less than 2. 14 . The electrochemical system of claim 1 , wherein the acidic stream and the basic stream are collected for direct carbon capture. 15 . The electrochemical system of claim 1 , wherein the system has a Coulombic efficiency of at least 80%. 16 . A system for direct ocean capture, comprising: an input configured to receive a source oceanwater; an electrochemical system configured to receive a first portion of the source oceanwater as an electrolyte; wherein the electrochemical system comprises: a cathode with a first side contacting a cathode gas chamber and a second side contacting a catholyte; and an anode with a first side contacting an anode gas chamber and a second side contacting an anolyte; wherein the catholyte and the anolyte are configured to receive the electrolyte and are separated by a separator; wherein the cathode is configured to catalyze a hydrogen evolution reaction and produce hydrogen gas and a basic stream with a pH less than or equal to 13 and greater than or equal to 7, and the anode is configured to catalyze a hydrogen oxidation reaction and produce an acidic stream with a pH greater than or equal to 1 and less than or equal to 7; and wherein the cathode gas chamber connects with the anode gas chamber via a flow channel such that the hydrogen gas flows from the anode to the cathode; a carbon dioxide stripping system configured to receive acidified oceanwater comprising a second portion of the source oceanwater and the acidic stream; wherein the carbon dioxide stripping system is configured to separate gaseous carbon dioxide and produce a decarbonized oceanwater stream; wherein the decarbonized oceanwater stream is configured to combine with the basic stream before being returned to the ocean. 17 . The system of claim 16 , wherein the cathode and the anode each comprise a gas diffusion electrode that separates a gas phase and a liquid phase. 18 . The system of claim 16 , wherein the second side of the cathode and the second side of the anode each comprises a layer configured to be a barrier to prevent a gas phase and a liquid phase from mixing; wherein the layer is selected from the group consisting of: a polymer layer, a ceramic layer, a layer with a positive electrical charge, and a layer with a negative electrical charge. 19 . The system of claim 18 , wherein the layer comprises an ionomer selected from the group consisting of a Nafion® ionomer, a Nafion® D520 ionomer, a Sustainion® ionomer, and a Versogen® PiperION-A5 ionomer. 20 . The electrochemical system of claim 18 , wherein the layer prevents buildup of precipitates on the electrodes when performing polarity switch to the cathode and the anode. 21 . The electrochemical system of claim 18 , wherein the layer prevents bubble formation on the cathode and the anode. 22 . The system of claim 16 , wherein the electrochemical system further comprises current collectors connected to the cathode and the anode for connecting the cathode and the anode to an external circuit. 23 . The system of claim 16 , wherein an ionic concentration of the electrolyte is higher than proton and hydroxide ion concentrations such that neutralization of the acidic and basic streams is minimized. 24 . The system of claim 16 , wherein the separator comprises a filter paper, a qualitative grade filter paper, a quantitative grade filter paper, a glass fiber filter, a quartz fiber filter, a chromatography filter paper, a coffee filter paper, a tea filter paper, a ceramic membrane, or a sodium superionic conductor membrane. 25 . The system of claim 16 , wherein the electrochemical system is configured to achieve a current density less than or equal to 500 mA/cm 2 . 26 . The system of claim 16 , wherein the electrochemical system has a configuration selected from the group consisting of: an H cell, a cell stack, a flow cell, and a flow stack. 27 . The system of claim 16 , wherein the basic stream has a pH greater than 12 and the acidic stream has a pH less than 2. 28 . The system of claim 16 , wherein the electrochemical system has a c