Molten carbonate fuel cell research at ORNL

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During charge or discharge of batteries with a binary molten salt mixture as t~he electrolyte, composition gradients are produced by the electrode reactions and the differences in mobilities of the electroactive and nonelectroactive ions. The effects of current density, electrode separatioa, and initial composition of the electrolyte are predicted by an analytical solution of the flux equations derived with transport properties similar to those of LiCI-KC1 mixtures. Numerical solution of the flux equations predicts the composition profiles in lithium sulfur battery analogs with LiC1-KCI mixtures of differing compositions. Either complete depletio,n of the electroactive constituent at one electrode, or precipitation of a solid phase at the electrodes, could result from the predicted composition gradients. Changes in electrolyte composition at the electrodes may also affect J-phase formation at the sulfur electrode during discharge. * Electrochemical Society Active Member. ) unless CC License in place (see abstract). ecsdl.org/site/terms_use address. Redistribution subject to ECS terms of use (see 169.230.243.252 Downloaded on 2015-02-18 to IP ) unless CC License in place (see abstract). ecsdl.org/site/terms_use address. Redistribution subject to ECS terms of use (see 169.230.243.252 Downloaded on 2015-02-18 to IP

“…(2), Equation 14]. The general one dimensional flux expressions may be written --JL* = D 0eL --ML* I/F [1] 0} --JK* = DOCK _ ME* I/F [2] 0}…”

Section: Flux Equations and Boundary Conditionsmentioning

confidence: 99%

Section: Flux Equations and Boundary Conditionsmentioning

confidence: 99%

mentioning

confidence: 99%

See 1 more Smart Citation

Steady‐State Composition Profiles in Mixed Molten Salt Electrochemical Devices: I . Lithium/Sulfur Battery Analogs

Vallet

Braunstein

1978

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“…Although a higher mobility of the lithium ion has been inferred from voltage relaxation data for an equimolar mixture of lithium and potassium carbonate (17) actual measurements of mobilities indicate that the lithium ion has a lower mobility than that of other alkali metal ions in sulfates (18), chlorides (19), bromides (20), and nitrates (21) over wide ranges of concentration. This high potassium content is evidently not caused by selective vaporization of lithium from this region by some mechanism, because the lithium was found in the lower, more positive regions of the gasket.…”

Section: Discussionmentioning

confidence: 99%

Transport of Electrolyte in Molten Carbonate Fuel Cells

Kunz¹

1987

The transport of electrolyte in molten carbonate fuel cell stacks was theoretically and experimentally investigated. The electrolyte was found to migrate from the end of a stack which is more positive in potential toward the end which is more negative due to the relative movement of the ionic species in the electrolyte. The potassium ion mobility was found to be higher than that of the lithium ion, resulting in a depletion in potassium concentration at the positive end and an increase at the negative end. The transport can be reduced to an acceptable level by the use of manifold gaskets that result in smaller shunt currents.

“…The electrodes thus behave phenomenologically as membranes permeable to carbonate ions but impermeable to Li + or K + ions (here designated L and K). In this case the migrational term becomes (2) /P/K V = tK c --XK and the boundary conditions at the two electrodes separated by a distance ~ are JL v=JK v=0 at ~=0 (anode) and at ~ =~ (cathode) [4] where the superscript V corresponds to the constant volume reference frame.…”

Section: Flux Equation Boundary Conditionsmentioning

confidence: 99%

Steady‐State Composition Profiles in Mixed Molten Salt Electrochemical Devices: II . Molten Carbonate Fuel Cell Analogs

Vallet¹,

Braunstein²

1979

Steady-state equations, derived previously for composition gradients in battery analogs with binary mixtures of molten salts as electrolytes, have been modified to apply to molten carbonate fuel cells. Since neither of the two like-charged cations of the electrolyte reacts at the electrodes, the concentration gradient arises only from the difference in the mobilities of the two cations. Conditions of current density, electrode separation, electrolyte composition, and temperature that favor either steady state or precipitation of a solid phase are presented in parametric form. Numerical solution of the diffusion-migration equation is used to predict the development with time of the concentration gradient. The computation also simulates the variations with time of emf between anode and cathode both during current flow and during the subsequent decay on open circuit. An electrochemical method for estimation of the interdiffusion coefficient and the ion mobility ratio in a binary electrolyte is outlined.