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In [[electrochemistry]], the '''Nernst equation''' is an equation that relates the equilibrium [[reduction potential]] of a [[half-cell]] in an [[electrochemical cell]] (or the total [[voltage]] ([[electromotive force]]) for a full cell) to the [[standard electrode potential]], [[Thermodynamic temperature|temperature]], [[Thermodynamic activity|activity]], and [[reaction quotient]] of the underlying reactions and species used.  It is named after the German physical chemist who first formulated it, [[Walther Nernst]].<ref name="isbn0-8412-1572-3">{{cite book |author=Orna, Mary Virginia; Stock, John |title=Electrochemistry, past and present |publisher=American Chemical Society |location=Columbus, OH |year=1989 |pages= |isbn=0-8412-1572-3 |oclc= 19124885|doi= |accessdate=}}</ref><ref name=Wahl2005>{{Cite journal | last = Wahl | year = 2005 | title = A Short History of Electrochemistry | journal = Galvanotechtnik | volume = 96 | issue = 8 | pages = 1820–1828 }}</ref>
 
The Nernst equation gives a formula that relates the numerical values of the [[concentration gradient]] to the [[electric gradient]] that balances it. For example, if a concentration gradient was established by dissolving KCl in half of a divided vessel that was originally full of H<sub>2</sub>O, and then a membrane permeable to K<sup>+</sup> ions was introduced between the two halves—empirically, an equilibrium situation would arise where the chemical concentration gradient (that would normally cause ions to move from the region of high concentration to the region of low concentration) could be balanced by an electrical gradient that opposes the movement of charge.
 
==Expression==
The two (ultimately equivalent) equations for these two cases (half-cell, full cell) are as follows:
:<math>
E_\text{red} = E^{\ominus}_\text{red} - \frac{RT}{zF} \ln\frac{a_\text{Red}}{a_\text{Ox}}
</math> &nbsp;&nbsp; (half-cell reduction potential)
:<math>
E_\text{cell} = E^{\ominus}_\text{cell} - \frac{RT}{zF} \ln Q
</math> &nbsp;&nbsp; (total cell potential)
where
*''E''<sub>red</sub> is the half-cell [[reduction potential]] at the temperature of interest
*''E''<sup><s>o</s></sup><sub>red</sub> is the [[standard electrode potential|''standard'' half-cell reduction potential]]
*''E''<sub>cell</sub> is the cell potential ([[electromotive force]]) at the temperature of interest
*''E''<sup><s>o</s></sup><sub>cell</sub> is the ''standard'' cell potential
*''R'' is the [[universal gas constant]]: ''R'' = 8.314&thinsp;472(15) J&thinsp;K<sup>&minus;1</sup>&thinsp;mol<sup>&minus;1</sup>
*''T'' is the [[absolute temperature]]
*''a'' is the chemical [[activity (chemistry)|activity]] for the relevant species, where ''a''<sub>Red</sub> is the [[reductant]] and ''a''<sub>Ox</sub> is the [[oxidant]]. ''a''<sub>X</sub>&nbsp;= ''γ''<sub>X</sub>''c''<sub>X</sub>, where ''γ''<sub>X</sub> is the [[activity coefficient]] of species X.  (Since activity coefficients tend to unity at low concentrations, activities in the Nernst equation are frequently replaced by simple concentrations.)
*''F'' is the [[Faraday constant]], the number of [[coulomb]]s per [[mole (unit)|mole]] of electrons: ''F'' = 9.648&thinsp;533&thinsp;99(24)×10<sup>4</sup> C&thinsp;mol<sup>&minus;1</sup>
*''z'' is the number of moles of [[electron]]s transferred in the cell reaction or [[half-reaction]]
*''Q'' is the [[reaction quotient]].
 
At room temperature (25 °C), ''RT/F'' may be treated like a constant and replaced by 25.693&nbsp;mV for cells.
 
The Nernst equation is frequently expressed in terms of base 10 [[logarithms]] (''i.e.'', [[common logarithm]]s) rather than [[natural logarithms]], in which case it is written, ''for a cell at 25 °C'':
 
:<math>
E = E^0 - \frac{0.05916\mbox{ V}}{z} \log_{10}\frac{a_\text{Red}}{a_\text{Ox}}.
</math>
 
The Nernst equation is used in [[physiology]] for finding the [[electric potential]] of a [[cell membrane]] with respect to one type of [[ion]].
 
==Nernst potential==
{{main|Reversal potential}}
 
The Nernst equation has a physiological application when used to calculate the potential of an ion of charge ''z'' across a membrane. This potential is determined using the concentration of the ion both inside and outside the cell:
 
:<math>E = \frac{R T}{z F} \ln\frac{[\text{ion outside cell}]}{[\text{ion inside cell}]} = 2.303\frac{R T}{z F} \log_{10}\frac{[\text{ion outside cell}]}{[\text{ion inside cell}]}.</math>
 
When the membrane is in [[thermodynamic equilibrium]] (i.e., no net flux of ions), the [[membrane potential]] must be equal to the Nernst potential. However, in physiology, due to active [[Na+/K+-ATPase|ion pumps]], the inside and outside of a cell are not in equilibrium. In this case, the [[resting potential]] can be determined from the [[Goldman equation]]:
 
<math>E_{m} = \frac{RT}{F} \ln{ \left( \frac{ \sum_{i}^{N} P_{M^{+}_{i}}[M^{+}_{i}]_\mathrm{out} + \sum_{j}^{M} P_{A^{-}_{j}}[A^{-}_{j}]_\mathrm{in}}{ \sum_{i}^{N} P_{M^{+}_{i}}[M^{+}_{i}]_\mathrm{in} + \sum_{j}^{M} P_{A^{-}_{j}}[A^{-}_{j}]_\mathrm{out}} \right) }</math>
 
*<math>E_{m}</math> = The membrane potential (in [[volt]]s, equivalent to [[joule]]s per [[coulomb]])
*<math>P_\mathrm{ion}</math> = the permeability for that ion (in meters per second)
*<math>[ion]_\mathrm{out}</math> = the extracellular concentration of that ion (in [[Mole (unit)|moles]] per cubic meter, to match the other  [[SI]] units, though the units strictly don't matter, as the ion concentration terms become a dimensionless ratio)
*<math>[ion]_\mathrm{in}</math> = the intracellular concentration of that ion (in moles per cubic meter)
*<math>R</math> = The [[ideal gas constant]] (joules per [[kelvin]] per mole)
*<math>T</math> = The temperature in [[kelvin]]
*<math>F</math> = [[Faraday constant|Faraday's constant]] (coulombs per mole)
 
The potential across the cell membrane that exactly opposes net diffusion of a particular ion through the membrane is called the Nernst potential for that ion. As seen above, the magnitude of the Nernst potential is determined by the ratio of the concentrations of that specific ion on the two sides of the membrane. The greater this ratio the greater the tendency for the ion to diffuse in one direction, and therefore the greater the Nernst potential required to prevent the diffusion.
 
A similar expression exists that includes r (the absolute value of the transport ratio). This takes transporters with unequal exchanges into account.  See: [[Sodium-Potassium Pump]] where the transport ratio would be 2/3. The other variables are the same as above.  The following example includes two ions: Potassium (K<sup>+</sup>) and sodium (Na<sup>+</sup>).  Chloride is assumed to be in equilibrium.
 
<math>V_{m} = \frac{RT}{F} \ln{ \left( \frac{ rP_{K}[K]_{o} + P_{Na}[Na]_{o}}{ rP_{K}[K]_{i} + P_{Na}[Na]_{i}} \right) }</math>
 
When Chloride (Cl<sup>&minus;</sup>) is taken into account, its part is flipped to account for the negative charge.
<math>V_{m} = \frac{RT}{F} \ln{ \left( \frac{ P_{K}[K]_{o} + P_{Na}[Na]_{o} + P_{Cl}[Cl]_{i}}{ P_{K}[K]_{i} + P_{Na}[Na]_{i} + P_{Cl}[Cl]_{o}} \right) }</math>
 
==Derivation==
===Using Boltzmann factors===
 
For simplicity, we will consider a solution of redox-active molecules that undergo a one-electron reversible reaction
 
:<math>\text{Ox} + e^- \rightleftharpoons \text{Red}\,</math>
 
and that have a standard potential of zero. The [[chemical potential]] <math>\mu_c</math> of this solution is the difference between the energy barriers for taking electrons from and for giving electrons to the [[Cyclic voltammetry|working electrode]] that is setting the solution's [[electrochemical potential]].  
 
The ratio of oxidized to reduced molecules, [Ox]/[Red], is equivalent to the probability of being oxidized (giving electrons) over the probability of being reduced (taking electrons), which we can write in terms of the [[Boltzmann factor]] for these processes:
 
:<math>
\frac{[\mathrm{Ox}]}{[\mathrm{Red}]}
= \frac{\exp \left(-[\mbox{barrier for losing an electron}]/kT\right)}
{\exp \left(-[\mbox{barrier for gaining an electron}]/kT\right)}
= \exp \left(\mu_c / kT \right).
</math>
 
Taking the natural logarithm of both sides gives
 
:<math>
\mu_c = kT \ln \frac{[\mathrm{Ox}]}{[\mathrm{Red}]}.
</math>
 
If <math>\mu_c \ne 0</math> at [Ox]/[Red] = 1, we need to add in this additional
constant:
 
:<math>
\mu_c = \mu_c^0 + kT \ln \frac{[\mathrm{Ox}]}{[\mathrm{Red}]}.
</math>
 
Dividing the equation by ''e'' to convert from chemical potentials to electrode potentials, and remembering that ''kT/e'' = ''RT/F'', we obtain the Nernst equation for the one-electron process
<math>\mathrm{Ox} + e^- \rightarrow \mathrm{Red}</math>:
 
:<math>
E = E^0 + \frac{kT}{e} \ln \frac{[\mathrm{Ox}]}{[\mathrm{Red}]}
= E^0 - \frac{RT}{F} \ln \frac{[\mathrm{Red}]}{[\mathrm{Ox}]}.
</math>
 
===Using thermodynamics (chemical potential)===
 
Quantities here are given per molecule, not per mole,
and so [[Boltzmann constant]] ''k'' and the electron charge ''e'' are used
instead of the gas constant ''R'' and Faraday's constant ''F''. To convert
to the molar quantities given in most chemistry textbooks, it is simply
necessary to multiply by Avogadro's number: <math>R = kN_A</math> and
<math>F = eN_A</math>.
 
The entropy of a molecule is defined as
:<math>
S \ \stackrel{\mathrm{def}}{=}\  k \ln \Omega,
</math>
where <math>\Omega</math> is the number of states available to the molecule.
The number of states must vary linearly with the volume ''V'' of the
system, which is inversely proportional to the concentration ''c'', so
we can also write the entropy as
:<math>
S = k\ln \ (\mathrm{constant}\times V) = -k\ln \ (\mathrm{constant}\times c).
</math>
The change in entropy from some state 1 to another state 2 is therefore
:<math>
\Delta S = S_2 - S_1 = - k \ln \frac{c_2}{c_1},
</math>
so that the entropy of state 2 is
:<math>
S_2 = S_1 - k \ln \frac{c_2}{c_1}.
</math>
If state 1 is at standard conditions, in which <math>c_1</math> is unity (e.g.,
1 atm or 1 M), it will merely cancel the units of <math>c_2</math>. We can, therefore,
write the entropy of an arbitrary molecule ''A'' as
:<math>
S(A) = S^0(A) - k \ln [A], \,
</math>
where <math>S^0</math> is the entropy at standard conditions and [''A''] denotes the
concentration of ''A''.
The change in entropy for a reaction
:<math>
aA + bB \rightarrow yY + zZ
</math>
is then given by
:<math>
\Delta S_\mathrm{rxn} = [yS(Y) + zS(Z)] - [aS(A) +  bS(B)]
= \Delta S^0_\mathrm{rxn} - k \ln \frac{[Y]^y [Z]^z}{[A]^a [B]^b}.
</math>
We define the ratio in the last term as the [[reaction quotient]]:
:<math>
Q = \frac{\prod_j a_j^{\nu_j}}{\prod_i a_i^{\nu_i}} \approx \frac{[Z]^z [Y]^y}{[A]^a [B]^b}.
</math>
 
where the numerator is a product of reaction product activities, ''a<sub> j</sub>'', each raised to the power of a [[stoichiometric coefficient]], ''ν<sub> j</sub>'', and the denominator is a similar product of reactant activities. All activities refer to a time ''t''. Under certain circumstances (see [[chemical equilibrium]]) each activity term such as <math>a_j^{\nu_j}</math> may be replaced by a concentration term, [''A''].
In an electrochemical cell, the cell potential ''E'' is the  
chemical potential available from redox reactions (<math>E = \mu_c/e</math>).
''E'' is related to
the [[Gibbs free energy|Gibbs energy]] change <math>\Delta G</math> only by a constant:
<math>\Delta G = -nFE</math>, where ''n'' is the number of electrons transferred and <math>F</math> is the Faraday constant.
There is a negative sign because a spontaneous reaction has a negative free energy <math>\Delta G</math> and a positive potential ''E''.
The Gibbs energy is related to the entropy by <math>G = H - TS</math>, where ''H'' is
the enthalpy and ''T'' is the temperature of the system. Using these
relations, we can now write the change in
Gibbs energy,
:<math>
\Delta G = \Delta H - T \Delta S = \Delta G^0 + kT \ln Q, \,
</math>
and the cell potential,
:<math>
E = E^0 - \frac{kT}{ne} \ln Q.
</math>
This is the more general form of the Nernst equation.
For the redox reaction
<math>\mathrm{Ox} + ne^- \rightarrow \mathrm{Red},</math>
<math>Q = \frac{[\mathrm{Red}]}{[\mathrm{Ox}]}</math>, and we have:
:<math>
E = E^0 - \frac{kT}{ne} \ln \frac{[\mathrm{Red}]}{[\mathrm{Ox}]}
= E^0 - \frac{RT}{nF} \ln \frac{[\mathrm{Red}]}{[\mathrm{Ox}]}
= E^0 - \frac{RT}{nF} \ln Q.
</math>
The cell potential at standard conditions <math>E^0</math> is often
replaced by the formal potential <math>E^{0'}</math>, which includes some small
corrections to the logarithm and is the potential that is actually measured
in an electrochemical cell.
 
==Relation to equilibrium==
 
At equilibrium, ''E'' = 0 and ''Q'' = ''K''. Therefore
:<math>
\begin{align}
0 &= E^o - \frac{RT}{nF} \ln K\\
\ln K &= \frac{nFE^o}{RT}
\end{align}
</math>
 
Or at [[Standard conditions for temperature and pressure|standard temperature]],
:<math>\log_{10} K = \frac{nE^o}{59.2\text{ mV}} \quad\text{at }T = 298 \text{ K}.</math>
 
We have thus related the [[standard electrode potential]] and the [[equilibrium constant]] of a redox reaction.
 
==Limitations==
 
In dilute solutions, the Nernst equation can be expressed directly in terms of concentrations (since activity coefficients are close to unity). But at higher concentrations, the true activities of the ions must be used. This complicates the use of the Nernst equation, since estimation of non-ideal activities of ions generally requires experimental measurements.
 
The Nernst equation also only applies when there is no net current flow through the electrode. The activity of ions at the electrode surface changes when there is current flow, and there are additional [[overpotential]] and resistive loss terms which contribute to the measured potential.
 
At very low concentrations of the potential-determining ions, the potential predicted by Nernst equation approaches toward ±∞. This is physically meaningless because, under such conditions, the [[exchange current density]] becomes very low, and there is no thermodynamic equilibrium necessary for Nernst equation to hold. The electrode is called to be unpoised in such case. Other effects tend to take control of the electrochemical behavior of the system.
 
==Significance to related scientific domains==
The equation has been involved in the scientific controversy of denying the reality of [[cold fusion]] phenomena.
 
==See also==
*[[Concentration cell]]
*[[Electrode potential]]
*[[Galvanic cell]]
*[[Goldman equation]]
*[[Membrane potential]]
*[[Nernst-Planck equation]]
 
==References==
{{Reflist}}
 
==External links==
* [http://www.nernstgoldman.physiology.arizona.edu/ Nernst/Goldman Equation Simulator]
* [http://www.physiologyweb.com/calculators/nernst_potential_calculator.html Nernst Equation Calculator]
* [http://thevirtualheart.org/GHKindex.html Interactive Nernst/Goldman Java Applet]
* [http://www.doitpoms.ac.uk/tlplib/pourbaix/index.php DoITPoMS Teaching and Learning Package- "The Nernst Equation and Pourbaix Diagrams"]
 
[[Category:Electrochemical equations]]

Revision as of 07:48, 13 October 2013

In electrochemistry, the Nernst equation is an equation that relates the equilibrium reduction potential of a half-cell in an electrochemical cell (or the total voltage (electromotive force) for a full cell) to the standard electrode potential, temperature, activity, and reaction quotient of the underlying reactions and species used. It is named after the German physical chemist who first formulated it, Walther Nernst.[1][2]

The Nernst equation gives a formula that relates the numerical values of the concentration gradient to the electric gradient that balances it. For example, if a concentration gradient was established by dissolving KCl in half of a divided vessel that was originally full of H2O, and then a membrane permeable to K+ ions was introduced between the two halves—empirically, an equilibrium situation would arise where the chemical concentration gradient (that would normally cause ions to move from the region of high concentration to the region of low concentration) could be balanced by an electrical gradient that opposes the movement of charge.

Expression

The two (ultimately equivalent) equations for these two cases (half-cell, full cell) are as follows:

Ered=EredRTzFlnaRedaOx    (half-cell reduction potential)
Ecell=EcellRTzFlnQ    (total cell potential)

where

At room temperature (25 °C), RT/F may be treated like a constant and replaced by 25.693 mV for cells.

The Nernst equation is frequently expressed in terms of base 10 logarithms (i.e., common logarithms) rather than natural logarithms, in which case it is written, for a cell at 25 °C:

E=E00.05916 Vzlog10aRedaOx.

The Nernst equation is used in physiology for finding the electric potential of a cell membrane with respect to one type of ion.

Nernst potential

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The Nernst equation has a physiological application when used to calculate the potential of an ion of charge z across a membrane. This potential is determined using the concentration of the ion both inside and outside the cell:

E=RTzFln[ion outside cell][ion inside cell]=2.303RTzFlog10[ion outside cell][ion inside cell].

When the membrane is in thermodynamic equilibrium (i.e., no net flux of ions), the membrane potential must be equal to the Nernst potential. However, in physiology, due to active ion pumps, the inside and outside of a cell are not in equilibrium. In this case, the resting potential can be determined from the Goldman equation:

Em=RTFln(iNPMi+[Mi+]out+jMPAj[Aj]iniNPMi+[Mi+]in+jMPAj[Aj]out)

  • Em = The membrane potential (in volts, equivalent to joules per coulomb)
  • Pion = the permeability for that ion (in meters per second)
  • [ion]out = the extracellular concentration of that ion (in moles per cubic meter, to match the other SI units, though the units strictly don't matter, as the ion concentration terms become a dimensionless ratio)
  • [ion]in = the intracellular concentration of that ion (in moles per cubic meter)
  • R = The ideal gas constant (joules per kelvin per mole)
  • T = The temperature in kelvin
  • F = Faraday's constant (coulombs per mole)

The potential across the cell membrane that exactly opposes net diffusion of a particular ion through the membrane is called the Nernst potential for that ion. As seen above, the magnitude of the Nernst potential is determined by the ratio of the concentrations of that specific ion on the two sides of the membrane. The greater this ratio the greater the tendency for the ion to diffuse in one direction, and therefore the greater the Nernst potential required to prevent the diffusion.

A similar expression exists that includes r (the absolute value of the transport ratio). This takes transporters with unequal exchanges into account. See: Sodium-Potassium Pump where the transport ratio would be 2/3. The other variables are the same as above. The following example includes two ions: Potassium (K+) and sodium (Na+). Chloride is assumed to be in equilibrium.

Vm=RTFln(rPK[K]o+PNa[Na]orPK[K]i+PNa[Na]i)

When Chloride (Cl) is taken into account, its part is flipped to account for the negative charge. Vm=RTFln(PK[K]o+PNa[Na]o+PCl[Cl]iPK[K]i+PNa[Na]i+PCl[Cl]o)

Derivation

Using Boltzmann factors

For simplicity, we will consider a solution of redox-active molecules that undergo a one-electron reversible reaction

Ox+eRed

and that have a standard potential of zero. The chemical potential μc of this solution is the difference between the energy barriers for taking electrons from and for giving electrons to the working electrode that is setting the solution's electrochemical potential.

The ratio of oxidized to reduced molecules, [Ox]/[Red], is equivalent to the probability of being oxidized (giving electrons) over the probability of being reduced (taking electrons), which we can write in terms of the Boltzmann factor for these processes:

[Ox][Red]=exp([barrier for losing an electron]/kT)exp([barrier for gaining an electron]/kT)=exp(μc/kT).

Taking the natural logarithm of both sides gives

μc=kTln[Ox][Red].

If μc0 at [Ox]/[Red] = 1, we need to add in this additional constant:

μc=μc0+kTln[Ox][Red].

Dividing the equation by e to convert from chemical potentials to electrode potentials, and remembering that kT/e = RT/F, we obtain the Nernst equation for the one-electron process Ox+eRed:

E=E0+kTeln[Ox][Red]=E0RTFln[Red][Ox].

Using thermodynamics (chemical potential)

Quantities here are given per molecule, not per mole, and so Boltzmann constant k and the electron charge e are used instead of the gas constant R and Faraday's constant F. To convert to the molar quantities given in most chemistry textbooks, it is simply necessary to multiply by Avogadro's number: R=kNA and F=eNA.

The entropy of a molecule is defined as

S=defklnΩ,

where Ω is the number of states available to the molecule. The number of states must vary linearly with the volume V of the system, which is inversely proportional to the concentration c, so we can also write the entropy as

S=kln(constant×V)=kln(constant×c).

The change in entropy from some state 1 to another state 2 is therefore

ΔS=S2S1=klnc2c1,

so that the entropy of state 2 is

S2=S1klnc2c1.

If state 1 is at standard conditions, in which c1 is unity (e.g., 1 atm or 1 M), it will merely cancel the units of c2. We can, therefore, write the entropy of an arbitrary molecule A as

S(A)=S0(A)kln[A],

where S0 is the entropy at standard conditions and [A] denotes the concentration of A. The change in entropy for a reaction

aA+bByY+zZ

is then given by

ΔSrxn=[yS(Y)+zS(Z)][aS(A)+bS(B)]=ΔSrxn0kln[Y]y[Z]z[A]a[B]b.

We define the ratio in the last term as the reaction quotient:

Q=jajνjiaiνi[Z]z[Y]y[A]a[B]b.

where the numerator is a product of reaction product activities, a j, each raised to the power of a stoichiometric coefficient, ν j, and the denominator is a similar product of reactant activities. All activities refer to a time t. Under certain circumstances (see chemical equilibrium) each activity term such as ajνj may be replaced by a concentration term, [A]. In an electrochemical cell, the cell potential E is the chemical potential available from redox reactions (E=μc/e). E is related to the Gibbs energy change ΔG only by a constant: ΔG=nFE, where n is the number of electrons transferred and F is the Faraday constant. There is a negative sign because a spontaneous reaction has a negative free energy ΔG and a positive potential E. The Gibbs energy is related to the entropy by G=HTS, where H is the enthalpy and T is the temperature of the system. Using these relations, we can now write the change in Gibbs energy,

ΔG=ΔHTΔS=ΔG0+kTlnQ,

and the cell potential,

E=E0kTnelnQ.

This is the more general form of the Nernst equation. For the redox reaction Ox+neRed, Q=[Red][Ox], and we have:

E=E0kTneln[Red][Ox]=E0RTnFln[Red][Ox]=E0RTnFlnQ.

The cell potential at standard conditions E0 is often replaced by the formal potential E0, which includes some small corrections to the logarithm and is the potential that is actually measured in an electrochemical cell.

Relation to equilibrium

At equilibrium, E = 0 and Q = K. Therefore

0=EoRTnFlnKlnK=nFEoRT

Or at standard temperature,

log10K=nEo59.2 mVat T=298 K.

We have thus related the standard electrode potential and the equilibrium constant of a redox reaction.

Limitations

In dilute solutions, the Nernst equation can be expressed directly in terms of concentrations (since activity coefficients are close to unity). But at higher concentrations, the true activities of the ions must be used. This complicates the use of the Nernst equation, since estimation of non-ideal activities of ions generally requires experimental measurements.

The Nernst equation also only applies when there is no net current flow through the electrode. The activity of ions at the electrode surface changes when there is current flow, and there are additional overpotential and resistive loss terms which contribute to the measured potential.

At very low concentrations of the potential-determining ions, the potential predicted by Nernst equation approaches toward ±∞. This is physically meaningless because, under such conditions, the exchange current density becomes very low, and there is no thermodynamic equilibrium necessary for Nernst equation to hold. The electrode is called to be unpoised in such case. Other effects tend to take control of the electrochemical behavior of the system.

Significance to related scientific domains

The equation has been involved in the scientific controversy of denying the reality of cold fusion phenomena.

See also

References

43 year old Petroleum Engineer Harry from Deep River, usually spends time with hobbies and interests like renting movies, property developers in singapore new condominium and vehicle racing. Constantly enjoys going to destinations like Camino Real de Tierra Adentro.

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