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Modeling in Electrochemical Engineering
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Introduction: Electrochemical Systems
• Electrochemical systems are devices or processes in which an ionic conductor mediates the inter-conversion of chemical and electrical energy
• The reactions by which this inter-conversion of energy occurs involve the transfer of charge (electrons) at the interface between an electronic conductor (the electrode) and an ionic conductor (the electrolyte)
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Introduction: Redox Reactions
• Individual electrode reactions are symbolized as reduction-oxidation (redox) processes with electrons as one of the reactants:
Ox ne Red
Ox = oxidized speciesRed = reduced speciese- = electronn = electron stoichiometry coefficient.
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Introduction: Thermochemical and Electrochemical Processes
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Introduction: Energy Producing and Energy Consuming Electrochemical Processes
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Introduction: Spontaneous Processes and Processes that Require Energy Input
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Introduction: Electrocatalysis
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Introduction: Anodic and Cathodic Reactions
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Introduction: Transport and Electrochemical Reactions
• Transport– Diffusion, convection, migration,
which is an electrophoretic effect on ions. The mobility and concentration of ions yields the mass transfer and Ohmic resistances in the electrolyte
• Electrochemical reaction– Electrode kinetics for an electron
charge transfer step as rate determining step (RDS) yields potential-dependent reaction rate. The overpotential is a measure of the activation energy (Arrhenius equation -> Butler-Volmer equation)
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Introduction: Transport
• Transport– Flux = diff. + conv. + migration
– Current density
– Electroneutralitysum of charges = 0
– Perfectly mixedprimary and secondary
i i i i i i i lD c c z m Fc N u
2sum of charg es
i i i i i l i i ii i i
F z D c z c z m Fc j u
2i i i l i i ii i
F z D c z m Fc
j
2i i i li
F z m Fc
conductivity
j
i ii
F z j N
ConcentrationDiffusivity
Flow velocity ChargeMobility
Ionic potentialFaraday’s constant
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Introduction: Conservation of Species and Charge
• Conservation of speciesn-1 species, n:th through chargeconservation
• Conservation of charge
• Net charge is not accumulated, produced or consumed in the bulk electrolyte
• For primary and secondary cases
ii i i i i i l i
cD c c z m Fc R
t
u
Reaction rate
2i i i l i i ii i
F z D c z m Fc
j
2 0i i i l i i ii i
F z D c z m Fc
0l
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Modeling of Electrochemical Cells
• Primary current distribution– Accounts only for Ohmic effects in the simulation of current density distribution
and performance of the cell:• Neglects the influence of concentration variations in the electrolyte• Neglects the influence of electrode kinetics on the performance of the cell, i.e.
activation overpotential is neglected (losses due to activation energy)
• Secondary current distribution– Accounts only for Ohmic effects and the effect of electrode kinetics in the
simulation of current density distribution and performance of the cell:• Neglects the influence of concentration variations in the electrolyte
• Tertiary current distribution– Accounts for Ohmic effects, effects of electrode kinetics, and the effects of
concentration variations on the performance of a cell
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Modeling of Electrochemical Cells
• Non-porous electrodes– Heterogeneous reactions– Typically used for electrolysis, metal winning, and electrodeposition
• Porous electrodes– Reactions treated as homogeneous reaction in models although they are heterogeneous
in reality– Typically used for batteries, fuel cells, and in some cases also for electrolysis
• Electrolytes– Diluted and supporting electrolytes– Concentrated electrolytes– ”Free” electrolytes with forced and free convection– ”Immobilized” electrolytes through the use of porous matrixes, negligible free convection,
rarely forced convection– Solid electrolytes, no convection
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• Assumptions:– Perfectly mixed
electrolyte– Negligible activation
overpotential– Negligible ohmic
losses in the anode structure
A First Example: Primary Current Distribution
Anode: Wire electrode
Cathodes: Flat-plateelectrodes
Cathodes: Flat-plateelectrodes
Electrolyte
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• Subdomain:– Charge continuity
• Boundary– Electrode potentials
at electrode surfaces– Insulation elsewhere
A First Example: Subdomain and Boundary Settings
Anode: Cell voltage = 1.3 VE0 = 1.2 VTotal cell (in this case ohmic) polarization = 100 mV
Cathodes: Electrode potential = 0 VE0 = 0 V(negligible overpotential)
Cathodes: 0 V
Electrolyte:
0l
l Ionic potential
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A First Example: Some Definitions
• Activation and concentration overpotential = 0
• Select the cathode as reference point
0s l E
0
0l s E
, 0s c
, ,cell s a s cE
, 0,0l c cE
, 0,l a cell aE E
s Electronic potential
cellE Cell voltage
l Ionic potential
a
c
At anode, index
At cathode, index
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A First Example: Some Results
• Current density distribution at tha anode surface
Highly active catalystInactive catalyst
• Potential distribution in the electrolyte
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A Second Example: Secondary Current Distribution
• Activation overpotential taken into account
• Charge transfer current at the electrode surfaces
• New boundary conditions
0s l E
0
1ct
g g
F Fi i exp exp
R T R T
l cti n
Exchange current densityFaraday’s constant
Gas constantCharge transfer coefficient
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Comparison: Primary and Secondary Current Distributions
• Current density distribution at the anode surface
Lower current density with equal cell voltage (1.3V) compared to primary case
• Polarization curves
Effect ofActivationoverpotential
Solid line = Primary
Dashed line = Secondary
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Comparison: Primary and Secondary Current Density Distribution, 0.1 A Total Current
• Dimensionless current density disribution, primary case
• Dimensionless current density disribution, secondary case
,
ct
ct average
icdd
i
Independent of total current
Dependentof total current
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Some Results: Mesh Convergence
• Polarization curves for three mesh refinements (four mesh cases)
• Total current, seven mesh cases (up to 799186 elements)
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Primary and Secondary Current Distributions: Summary and Remarks
• Primary case gives less uniform current distribution than the secondary case: – The addition of charge transfer resistance through the activation overpotential
forces the current to become more uniform
• Secondary current density distribution is not independent of total current:– The charge transfer resistance decreases with increasing current density
(overpotential increases proportional to the logarithm of current density for high current density)
• Home work:– The geometry is symmetric in this example. Use this geometry and treat the
wire electrode as a bipolar electrode placed in between an anode and a cathode
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Tertiary Current Density Distribution
• Use the secondary current distribution case as starting point
• Add the flow equations, in this case from single phase laminar flow Navier-Stokes
• Solve only for the flow
• Add equations for mass transport, in this chase the Nernst-Planck equations
• Introduce the concentration dependence on the reaction kinetics
• Solve the fully coupled material and charge balances using the already solved flow field
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Results: Concentration and Current Density Distribution
Main direction of the flow Stagnation in the flowresults in lower concentration
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Concluding Remarks
• Use a primary current distribution as the starting point• Introduce reaction kinetics to obtain secondary current distribution• Introduce a decoupled flow field• Introduce material balances and concentration dependency in the
reaction kinetics to obtain a tertiary current distribution– Several options:
• Supporting electrolyte where the conductivity is independent of concentration • All charged species are balanced and are combined in the electroneutrality condition• All charged species are balanced but they are combined using Poisson’s equation