Combined corrosion mitigation and hydrogen isotope extraction from molten salts

What is claimed is: 1 . A molten salt treatment system comprising a galvanic cell, the galvanic cell including a first electrode comprising an active metal, the active metal exhibiting electrochemical and chemical reactivity with an impurity of the molten salt, the galvanic cell including a second electrode comprising a catalyst or electrocatalyst for hydrogen generation, the galvanic cell further comprising a hydrogen permeator, wherein the first electrode and the second electrode are separated by a molten salt pathway. 2 . The molten salt treatment system of claim 1 , the active metal comprising an alkaline metal or an alkaline earth metal. 3 . The molten salt treatment system of claim 2 , the active metal comprising beryllium or lithium. 4 . The molten salt treatment system of claim 1 , wherein the active metal is a component of an alloy, a composite, a layered structure, or a functionally graded material. 5 . The molten salt treatment system of claim 1 , the second electrode comprising the hydrogen permeator. 6 . The molten salt treatment system of claim 4 , the hydrogen permeator comprising the catalyst and/or electrocatalyst for hydrogen generation. 7 . The molten salt treatment system of claim 1 , the catalyst and/or electrocatalyst for hydrogen generation comprising a noble metal. 8 . The molten salt treatment system of claim 1 , the hydrogen permeator comprising palladium, vanadium, niobium, or tantalum. 9 . The molten salt treatment system of claim 8 , the hydrogen permeator comprising a palladium alloy. 10 . The molten salt treatment system of claim 9 , the palladium alloy comprising a palladium/silver alloy. 11 . The molten salt treatment system of claim 1 , the galvanic cell further comprising a reference electrode. 12 . The molten salt treatment system of claim 11 , the reference electrode being in electrical communication with a circuit breaker of the galvanic cell. 13 . The molten salt treatment system of claim 1 , further comprising a load control element. 14 . The molten salt treatment system of claim 1 , further comprising a hydrogen collection manifold. 15 . The molten salt treatment system of claim 1 , further comprising a thermal cycling adsorption process configured for hydrogen isotope separation. 16 . The molten salt treatment system of claim 1 , the first electrode further comprising a replaceable component, the replaceable component comprising the active metal. 17 . A method for treating a molten salt, the method comprising: flowing a molten salt along a pathway, the pathway separating a first electrode from a second electrode, the first electrode comprising an active metal, the second electrode comprising a catalyst or electrocatalyst for hydrogen generation; closing a galvanic circuit, and thereby encouraging chemical and/or electrochemical reactions in the molten salt, a reactant of the chemical and/or electrochemical reactions comprising a corrosive impurity of the molten salt, reaction products of the electrochemical and/or chemical reactions including hydrogen gas; and separating the hydrogen gas from the molten salt. 18 . The method of claim 17 , further comprising separating tritium from the hydrogen gas. 19 . The method of claim 17 , further comprising at a later time opening the galvanic circuit. 20 . The method of claim 19 , wherein the galvanic circuit is opened upon a control signal from a reference electrode. 21 . The method of claim 17 , wherein the hydrogen gas is separated from the molten salt via a hydrogen permeator on the pathway. 22 . The method of claim 17 , wherein the pathway is fluidly connected to a molten salt blanket of a nuclear reactor, the method further comprising flowing the molten salt from the nuclear reactor to the pathway.