Further Physical Chemistry: Electrochemistry session 8

00:15:40
https://www.youtube.com/watch?v=zcMTU8SgSc4

Summary

TLDRIn this session, the focus is on electrode kinetics and their influence on current in electrochemical cells. The Butler-Volmer equation is crucial as it links current density to overpotential, balancing between oxidative and reductive processes. Overpotential is defined as the difference between the equilibrium potential and the actual applied potential. As overpotential values become extreme, one of the reactions tends to dominate, thereby influencing the overall current. The exchange current density (J0) and the symmetry factor (alpha) are pivotal but cannot be measured directly. J0 is an indicator of charge transfer rate at equilibrium, while alpha provides a symmetry measure between reduction and oxidation processes. High alpha (e.g., alpha=0.5) suggests equal rates of reduction and oxidation. Tafel plots are used to determine these parameters by plotting log current density against overpotential, revealing linearity at higher potentials. High exchange current densities allow delivering desired currents at lower overpotentials, hence promoting efficiency, while electrode material also affects this property, as seen in comparison between different metals like platinum and mercury. Current variations and curves obtained from experiments help deduce properties of electrodes and aid in understanding the kinetics of electron exchanges. Recognizing how factors such as electrode surface properties and solution interactions influence exchange current densities is vital for advancing electrochemical applications.

Takeaways

  • šŸ”‹ Understanding electrode kinetics is essential for electrochemical cell performance.
  • šŸ“ˆ The Butler-Volmer equation relates current density to potential variation.
  • āš–ļø Overpotential impacts which reaction process dominates in cell reactions.
  • šŸ”‘ Exchange current density is crucial for efficient charge transfer.
  • šŸ“Š Tafel plots help determine J0 and alpha, crucial for electrode analysis.
  • āš™ļø Electrode material and reaction nature affect exchange current density.
  • šŸŒ Symmetry factor alpha influences the rate of oxidation vs. reduction.
  • šŸ”‘ High exchange current density allows efficient energy use in cells.
  • šŸ“‰ Low overpotentials mean observable contributions from both processes.
  • šŸ”¬ Catalyst properties of materials like platinum influence electrochemical reactions.

Timeline

  • 00:00:00 - 00:05:00

    In this video, the discussion begins with electrode kinetics and the influence of potentials on electrochemical cells, highlighting the Butler-Volmer equation that describes the balance of reductive and oxidative processes through the current density (J). The current in the cell is a resultant of these processes, affected by overpotential (Ī·) and exchange current density (Jā‚€). An important factor, the symmetry factor (Ī± = 0.5), illustrates equal rates of reduction and oxidation.

  • 00:05:00 - 00:10:00

    The relationship between current density and overpotential is further shown through discussions on Tafel plots, which are derived from linearizing the Butler-Volmer equation under conditions where either the oxidative or reductive processes dominate. These plots graphically represent the logarithm of current density against overpotential, helping to determine the symmetry factor and exchange current density. Deviations from linearity at small overpotentials indicate concurrent oxidative and reductive contributions to the current.

  • 00:10:00 - 00:15:40

    Exchange current density and its dependence on electrode kinetics are discussed, with factors affecting it like adsorption and reaction complexity. Electrode materials, like platinum, influence exchange rates due to their catalytic properties. The comparison between reactions on platinum versus mercury demonstrates differences in reaction mechanisms and rates. The balance between oxidation and reduction rates also forms key insights into current-potential behaviors, highlighting the significance of kinetics and electrode effects on electrochemical processes.

Mind Map

Video Q&A

  • What is the Butler-Volmer equation?

    The Butler-Volmer equation relates the current density of an electrochemical cell to the overpotential by balancing the oxidative and reductive processes.

  • What does overpotential in electrochemistry mean?

    Overpotential is the difference between the equilibrium potential and the potential applied to an electrochemical cell.

  • What is exchange current density?

    Exchange current density is the measure of the rate of charge transfer at an electrode at equilibrium, relevant for understanding electrochemical reaction kinetics.

  • What is the significance of the symmetry factor alpha?

    Alpha is a measure of how equally oxidative and reductive processes contribute to the observed current, influencing the shape of Tafel plots.

  • What are Tafel plots used for?

    Tafel plots are used to determine the exchange current density and the symmetry factor by plotting the log of current density against overpotential.

  • How does a high exchange current density affect an electrode?

    A high exchange current density means that a smaller overpotential is needed to achieve a specific current, indicating efficient charge transfer.

  • What influences the exchange current density?

    Factors such as electrode material, the nature of the electrochemical reaction (e.g., single electrons vs. bond breaking), and adsorption affect exchange current density.

  • Why is platinum effective as a catalyst?

    Platinum effectively balances the formation and breaking of metal-hydrogen bonds, making it an efficient catalyst in reactions like hydrogen evolution.

  • How does alpha affect the rate of oxidation and reduction?

    The symmetry factor alpha determines which of the oxidative or reductive process is favored, affecting the response of current to overpotential.

  • What role do Tafel plots serve in electrochemistry?

    They help visualize and analyze the relationship between current density and overpotential, providing insights into electrode kinetics and reaction dynamics.

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  • 00:00:00
    in our last session we looked at
  • 00:00:02
    electrode kinetics and how these would
  • 00:00:04
    have an effect on the current at an
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    electrode so now what we're going to do
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    is examine what happens as we vary
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    potentials as we apply a potential to an
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    electrochemical cell we introduced last
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    time the butler-volmer equation which
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    showed us how we balanced a reductive
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    process with an oxidative process
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    remember that we were talking about J in
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    terms of current density and the
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    butler-volmer equation shows how this
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    varies with respect to the applied
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    potential this over potential eater the
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    total current sum is therefore the sum
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    of the oxidative process and the
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    reductive process both of these we see
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    as eat a term this over potential term
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    appears in both so both are affected by
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    the potential that we apply
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    fundamentally the observed current that
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    we see in our cell only applies on the
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    exchange current density which this J
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    zero and our over potential eater our
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    alpha term that we've expressed here is
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    simply a measure of the symmetry between
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    the oxidative and reductive processes
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    where alpha is 0.5 the rate of reduction
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    is the same as the rate of oxidation at
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    each electrode where the number of
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    electrons exchanged is equal to 1 okay
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    so now let's look at how current varies
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    with over potential this graph that we
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    showed in the last slide simply shows
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    the anode rate and the cathode rate so
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    the oxidative current here in red on the
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    top by convention this is positive while
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    the cathode current the reduction is
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    happening here in blue and what we see
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    is the sum of these two curves this
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    purple line up the middle shows what
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    direction the current flows as we apply
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    different over potentials to our cell so
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    remember the over potential is simply
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    the difference between the equilibrium
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    potential and the potential that we're
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    applying to our cell what we see very
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    rapidly is as we get to extreme values
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    of over potential one component very
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    rapidly begins to dominate so we're eta
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    is plus or minus naught point one so if
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    you have plus or minus naught point one
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    over a potential applied to our cell we
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    generally get one term dominating if we
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    look at the left-hand component we're
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    saying that this oxidative component
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    dominates if our
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    overpotential is greater than plus nor
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    point one volts while the reductive
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    process would dominate if our over
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    potential is less than - nor point one
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    volts so what this means overall is that
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    unless we have a very very small over
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    potential we will really only see the
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    current coming from either the oxygen
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    process or the reductive process only at
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    very small magnitudes of n will we see
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    our currents actually having competition
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    between oxidation and reduction what we
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    now need to do is think about what's
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    this j0 this exchange current density
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    and this symmetry component let's we
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    need to find out what these terms are so
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    our exchange current density and our
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    symmetry factor alpha cannot be measured
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    directly so this exchange current
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    density is simply what the current is or
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    the exchange current at equilibrium is
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    while the Alpha component is simply a
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    reduction contribution to the Gibbs
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    energy so the greater alpha remember
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    this is a proportion it's a fraction the
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    greater alpha is the greater the
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    reductive component to the overall Gibbs
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    energy if we look at a situation where
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    we have alpha is not 0.5 so this is a
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    symmetrical situation where the
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    reductive and oxidative processes are
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    contributing equally to the overall
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    current we observe well we see that yes
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    at these extreme values of our over
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    potential we have our reduction
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    dominating at very low over potentials
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    and we have our oxidation dominating and
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    very high over potentials so let's
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    consider what happens when ETA is
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    greater than 0.1 volts or the magnitude
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    of ETA is greater than 0.1 volts well if
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    we say that ETA is greater than not 0.1
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    plus not 0.1 volts if we look at this
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    reductive term the reductive term simply
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    shrinks to zero we get a very simple
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    format for our overall current density
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    if on the other hand we consider what
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    happens when eta is less than - not 0.1
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    volts now our oxidative term shrinks
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    into obscurity and we get a simple
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    expression in terms of the reductive
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    process now that we've established this
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    how do we now find our exchange current
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    density and alpha well we have an
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    equation here we've seen equations like
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    this before it's this a very similar
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    format
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    Rini equation which you've dealt with
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    before you've linearized before so so if
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    we think about linearizing this form of
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    equation we get on to plotting data on a
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    graph the name for these plots are
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    called Tafel plots they're lie the
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    determination of our fractional symmetry
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    components and our exchange current
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    density in order to do one of these
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    plots we simply plot the log of the
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    current density against the over
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    potential so remember we simplified the
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    butler-volmer equation for a particular
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    case of high e to high over potential
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    and remember one of these terms drops
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    out depending on whether we're negative
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    not point one or positive not point one
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    so let's look at the reductive process
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    to start with so we're dealing with eta
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    is less than - not point one volts if we
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    take logarithms of both sides we simply
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    get up this sort of relationship and we
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    should immediately recognize this where
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    we have a y equals MX plus C type
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    equation where the variable
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    eita we're plotting against log of J and
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    we should get a graph with a gradient of
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    alpha F over RT and sure enough when we
  • 00:05:34
    plot these we find that the reductive
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    component where where eta is less than -
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    not 0.1 volts we see sure enough we get
  • 00:05:42
    a linear range it starts to deviate
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    that's very low over potentials because
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    as we said we start to get a
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    contribution from the oxidative
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    component so that causes a deviation
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    from linearity so this gives us an
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    equation for the reductive component and
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    we can do the same for the oxidative
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    component and we get the right-hand side
  • 00:06:00
    of the curve we simply plot log J
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    against the over potential which allows
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    us to very simply find the exchange
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    current density if we look at this
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    remember y equals MX plus C type graph
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    our intercept should be log of j0 the
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    log of that exchange current density and
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    the gradient allows us to easily find
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    this symmetry component alpha it's
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    important to remember that at Athol plot
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    will not be symmetrical so depending on
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    the value of our symmetry factor alpha
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    we will get a different shaped Ifill
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    plot so if alpha is not point two we
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    enhance the oxidative component we have
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    a much greater contribution to the
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    current from the
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    component while if alpha is much greater
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    we have the simply factors much greater
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    that means we have a much greater
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    contribution from the reductive
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    component but regardless of what this
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    value of alpha might be this intercept
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    will be common to both sides of the
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    graph and both will give us a value for
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    that exchange current density let's look
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    at the features of these Tuffle plots we
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    said a little bit about this deviation
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    from linearity they're curved at these
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    small over potentials because what's
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    happening is we get both reduction and
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    oxidation contribute to the current that
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    we observe if we go to higher over
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    potentials the competing process tends
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    to zero and we get increasing
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    conformation to this linear fit the
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    straight-line section will allow us to
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    find our exchange current density J 0
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    from the intercept and alpha from the
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    gradient it's worth giving some thought
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    to these logarithms often when we do
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    theory we use natural logarithms because
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    of the prevalence of the exponential
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    term e but when we do things practically
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    we almost always plot log base 10 so
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    often we use this log base 10 but it's
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    important to remember they are the same
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    mathematical function and there's a
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    simple linear relationship between them
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    where the log of one term J is simply
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    two point three or three times the log
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    base 10 of J so always remember that
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    that these logarithmic relationships are
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    the same just with a scaling factor the
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    symmetry factor can be a source of some
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    confusion so it's worth spending some
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    time on what this means as well we
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    introduced it earlier as a free energy
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    contribution from the reductive process
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    but it's simply a balance between those
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    oxidation and reduction currents so at
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    very low alpha if we look at how the
  • 00:08:18
    current responds to the over potential
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    we see at low alpha the oxide of current
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    responds much more readily to the
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    applied over potential than the
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    reductive current so oxidation will be
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    favored at low alpha where we see this
  • 00:08:34
    positive response and it increases much
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    more rapidly with the applied over
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    potential if we go the other way and
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    consider alpha of 0.7 we see the reverse
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    is true where we get the reduction
  • 00:08:45
    process favored where reduction current
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    increases much more rapidly with ETA
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    because that kind of gives an overview
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    of what this symmetry
  • 00:08:52
    factories the exchange current density
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    however is slightly more unusual to
  • 00:08:57
    consider this is simply termed the
  • 00:08:59
    equilibrium current exchange it is the
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    rate of charge transfer at the electrode
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    at equilibrium so there's no net
  • 00:09:06
    transfer but it's a measure of how much
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    charge comes from the ions at the
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    surface into the electrode or from the
  • 00:09:11
    electrode up to the ions remember those
  • 00:09:13
    two terms balance the more readily they
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    can exchange those electrons the more
  • 00:09:17
    readily the system can deliver a current
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    without significant energy loss
  • 00:09:21
    fundamentally what this does is it
  • 00:09:23
    affects the over potential required to
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    deliver a specific current so if we look
  • 00:09:28
    at the graph this is showing what
  • 00:09:30
    happens it to the current voltage
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    response and at different exchange
  • 00:09:33
    current densities so let's firstly
  • 00:09:36
    define a fixed current density of not
  • 00:09:39
    0.5 micro amps per square meter so to
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    deliver this current we find that if we
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    have a high exchange current density at
  • 00:09:47
    our electrode so if our electrode
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    naturally has a high exchange current
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    density we only have to apply an over
  • 00:09:53
    potential of 0.2 volts however as we
  • 00:09:57
    have lower and lower exchange current
  • 00:10:00
    densities we find we have to apply a
  • 00:10:02
    greater and greater over potential in
  • 00:10:04
    order to deliver that same current if we
  • 00:10:08
    have a low exchange current density that
  • 00:10:09
    means we have a lot less charge transfer
  • 00:10:11
    at equilibrium which means we have to
  • 00:10:13
    apply this larger over potential to
  • 00:10:14
    drive the net current forward so what
  • 00:10:17
    kind of factors affect the exchange
  • 00:10:18
    current density well we said that there
  • 00:10:21
    are electrode processes and we said it
  • 00:10:22
    was a characteristic of the electrode
  • 00:10:23
    and the solute that we were looking at
  • 00:10:25
    so let's consider the kinetics of what's
  • 00:10:27
    going on if we think about what's going
  • 00:10:29
    on at the electrode if we consider
  • 00:10:31
    something with a high exchange current
  • 00:10:34
    density so quite a high exchange current
  • 00:10:35
    density is 10 amps per square meter so
  • 00:10:38
    an example of this is a single electron
  • 00:10:40
    process so iron ferrous ion it can be
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    reduced to another iron ferrocyanide
  • 00:10:44
    compound but notice there's only a
  • 00:10:46
    single electron going on there and
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    there's no bonds being broken so there's
  • 00:10:51
    no chip no significant change in the
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    solute so it's very easy for it to pick
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    up an electron very easy for it to give
  • 00:10:57
    it up which leads to us having a higher
  • 00:10:59
    exchange current density another thing
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    which favors a high exchange current
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    density is having no adsorption
  • 00:11:06
    so adsorption is when a species will
  • 00:11:08
    chemically bond with the surface so in
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    this case I've shown hydrogen ions
  • 00:11:13
    receiving electron and the hydrogen atom
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    forms a chemical bond of the surface
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    this reduces the exchange current
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    density so if we have no adsorption then
  • 00:11:22
    we would tend to get a higher exchange
  • 00:11:23
    current density and if the reactant and
  • 00:11:25
    product have very similar properties
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    then again we would expect to have a
  • 00:11:28
    high exchange currency easy for those
  • 00:11:30
    electrons to exchange across the
  • 00:11:32
    interface if however we consider a low
  • 00:11:35
    exchange current density the reverse
  • 00:11:36
    would apply so if you have a very
  • 00:11:38
    complex process we have lots of things
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    going on at once or if we have to break
  • 00:11:41
    a chemical bond or if we had to adsorb
  • 00:11:45
    onto the surface these are factors that
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    would favor a low exchange current
  • 00:11:50
    density an example of this where we have
  • 00:11:52
    the azide nitrogen couple picking up an
  • 00:11:55
    electron the exchange current density is
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    absolutely miniscule because the
  • 00:12:00
    strength of the nitrogen bond makes it
  • 00:12:02
    extremely difficult to drive that
  • 00:12:05
    process forward the electrode material
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    also affects the exchange current
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    density so for a given reaction so I'm
  • 00:12:13
    just going to talk about the reduction
  • 00:12:14
    of protons in a hydrogen standard
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    electrode so let's consider this couple
  • 00:12:19
    at a platinum electrode we have an
  • 00:12:22
    exchange current density of 10 minus 3
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    so one ten-thousandth of an amp per
  • 00:12:26
    square meter while if we deal with a
  • 00:12:28
    mercury electrode our exchange current
  • 00:12:30
    density drops massively and
  • 00:12:33
    fundamentally this happens because of a
  • 00:12:34
    different mechanism of exchange a
  • 00:12:36
    different way in which the charge is
  • 00:12:38
    transferred Platinum fundamentally has
  • 00:12:41
    catalytic properties this is something
  • 00:12:42
    that should be well known to you and is
  • 00:12:44
    dealt with quite extensively in the
  • 00:12:46
    inorganic chemistry side of things but
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    as a result of those catalytic
  • 00:12:50
    properties this surface effects the
  • 00:12:51
    kinetics of the process so let's explore
  • 00:12:54
    the process a little bit our first step
  • 00:12:56
    is hydrogen being reduced and absorbed
  • 00:13:01
    bringing to the surface so we simplify
  • 00:13:03
    on this methyl hydrogen bond here we
  • 00:13:06
    then have one of two process that can
  • 00:13:07
    then occur either a second hydrogen
  • 00:13:10
    which which is adsorbed to the surface
  • 00:13:12
    can form a bond directly with the
  • 00:13:14
    hydrogen and break the metal hydrogen
  • 00:13:16
    bonds and release our h2 gas or what we
  • 00:13:19
    can have is
  • 00:13:20
    we can have another proton coming in and
  • 00:13:22
    being reduced and simultaneously falling
  • 00:13:27
    that hydrogen gas release so these are
  • 00:13:31
    the three steps that we wish to consider
  • 00:13:32
    but depending on the rates of each one
  • 00:13:35
    and the rate at which each one occurs
  • 00:13:37
    will affect the overall rate of our
  • 00:13:39
    reaction for mercury and lead a metal
  • 00:13:44
    hydrogen bond is very very weak so that
  • 00:13:46
    means that this methyl hydrogen bond
  • 00:13:47
    formation becomes the rate determining
  • 00:13:49
    step if we consider step B where we have
  • 00:13:54
    the adsorbed hydrogen coming together to
  • 00:13:56
    form a ch2 gas in platinum
  • 00:13:59
    this becomes the rate determining step
  • 00:14:01
    because the methyl hydrogen bond is
  • 00:14:03
    considerably stronger so this is our
  • 00:14:05
    rate determining step in platinum step C
  • 00:14:08
    is generally slower because it involves
  • 00:14:11
    more species but this can also happen in
  • 00:14:13
    platinum as well but we need to factor
  • 00:14:15
    in the relative strengths of these
  • 00:14:17
    methyl hydrogen bonds and for a good
  • 00:14:19
    catalyst it has to strike a balance
  • 00:14:21
    between steps it has to strike a balance
  • 00:14:23
    between the formation of the methyl
  • 00:14:25
    hydrogen bond and then the subsequent
  • 00:14:26
    breaking of methyl hydrogen bonds it
  • 00:14:29
    just so happens that platinum strikes
  • 00:14:30
    its balance and makes it very effective
  • 00:14:32
    as a catalyst while for mercury LED and
  • 00:14:36
    so on this bond is very weak which means
  • 00:14:39
    it doesn't favor the formation and the
  • 00:14:41
    surface adsorption of hydrogen when
  • 00:14:46
    we're considering our current potential
  • 00:14:48
    curves we need to consider both the
  • 00:14:50
    oxidation and reduction currents because
  • 00:14:52
    they both contribute towards the process
  • 00:14:54
    that we measure the symmetry factors the
  • 00:14:57
    rate at which oxidation and reduction
  • 00:14:59
    contribute affect the shapes of the
  • 00:15:01
    curves that we've observed so whether we
  • 00:15:03
    have a process which strongly favors
  • 00:15:05
    oxidation or strongly favors the
  • 00:15:07
    reduction these all work together to
  • 00:15:09
    affect the shape of the curve that we
  • 00:15:11
    observe and fundamentally when we make
  • 00:15:12
    our measurements and look at the rate at
  • 00:15:14
    which the current is affected by the
  • 00:15:16
    overpotential the shape of the curve
  • 00:15:18
    gives us insight to the processes going
  • 00:15:19
    on at those electrodes the exchange
  • 00:15:22
    current is also something that's worth
  • 00:15:23
    looking at as well because the exchange
  • 00:15:25
    current affects the ability for a given
  • 00:15:28
    cell to deliver a current at a given
  • 00:15:30
    over potential and these exchange
  • 00:15:33
    currents are affected directly by
  • 00:15:35
    solution kinetics and electrode effects
Tags
  • Electrochemistry
  • Butler-Volmer Equation
  • Overpotential
  • Exchange Current Density
  • Tafel Plots
  • Symmetry Factor
  • Electrode Kinetics
  • Current Density
  • Reductive Process
  • Oxidative Process