World Library  
Flag as Inappropriate
Email this Article

Absolute electrode potential

Article Id: WHEBN0015407327
Reproduction Date:

Title: Absolute electrode potential  
Author: World Heritage Encyclopedia
Language: English
Subject: Glossary of engineering, Glossary of physics, Electrode potential, Electric potential
Publisher: World Heritage Encyclopedia

Absolute electrode potential

Absolute electrode potential, in electrochemistry, according to an IUPAC definition,[1] is the electrode potential of a metal measured with respect to a universal reference system (without any additional metal–solution interface).


According to a more specific definition presented by Trasatti,[2] the absolute electrode potential is the difference in electronic energy between a point inside the metal (Fermi level) of an electrode and a point outside the electrolyte in which the electrode is submerged (an electron at rest in vacuum).

This potential is difficult to determine accurately. For this reason, standard hydrogen electrode is typically used for reference potential. The absolute potential of the SHE is 4.44 ± 0.02 V at 25 °C. Therefore, for any electrode at 25 °C:

E^M_{\rm{(abs)}} = E^M_{\rm{(SHE)}}+(4.44 \pm 0.02)\ {\mathrm V}


E is electrode potential
V is volt
M denotes the electrode made of metal M
(abs) denotes the absolute potential
(SHE) denotes the electrode potential relative to the standard hydrogen electrode.

A different definition for the absolute electrode potential (also known as absolute half-cell potential and single electrode potential) has also been discussed in the literature.[3] In this approach, one first defines an isothermal absolute single-electrode process (or absolute half-cell process.) For example, in the case of a generic metal being oxidized to form a solution-phase ion, the process would be

M(metal) → M+(solution) + e(gas)

For the hydrogen electrode, the absolute half-cell process would be

1/2H2 (gas)H+(solution) + e(gas)

Other types of absolute electrode reactions would be defined analogously.

In this approach, all three species taking part in the reaction, including the electron, must be placed in thermodynamically well-defined states. All species, including the electron, are at the same temperature, and appropriate standard states for all species, including the electron, must be fully defined. The absolute electrode potential is then defined as the Gibbs free energy for the absolute electrode process. To express this in volts one divides the Gibb’s free energy by the negative of Faraday’s constant.

Rockwood's approach to absolute-electrode thermodynamics is easily expendable to other thermodynamic functions. For example, the absolute half-cell entropy has been defined as the entropy of the absolute half-cell process defined above.[4] An alternative definition of the absolute half-cell entropy has recently been published by Fang et al.[5] who define it as the entropy of the following reaction (using the hydrogen electrode as an example):

1/2H2 (gas) → H+(solution) + e(metal)

This approach differs from the approach described by Rockwood in the treatment of the electron, i.e. whether it is placed in the gas phase or in the metal.


The basis for determination of the absolute electrode potential under the Trasatti definition is given by the equation:

E^M{\rm (abs)} = \phi^M + \Delta ^M_S \psi


EM(abs) is the absolute potential of the electrode made of metal M
\phi^M is the electron work function of metal M
\Delta ^M_S \psi is the contact (Volta) potential difference at the metal(M)–solution(S) interface.

For practical purposes, the value of the absolute electrode potential of the standard hydrogen electrode is best determined with the utility of data for an ideally-polarizable mercury (Hg) electrode:

E^\ominus {\rm (H^+/H_2)(abs)} = \phi^{\rm{Hg}} + \Delta ^{\rm{Hg}} _S \psi^\ominus_{\sigma=0} - E^{\rm{Hg}}_{\sigma=0}\rm{(SHE)}


E^\ominus {\rm (H^+/H_2)(abs)} is the absolute standard potential of the hydrogen electrode
σ = 0 denotes the condition of the point of zero charge at the interface.

The types of physical measurements required under the Rockwood definition are similar to those required under the Trasatti definition, but they are used in a different way, e.g. in Rockwood's approach they are used to calculate the equilibrium vapor pressure of the electron gas. The numerical value for the absolute potential of the standard hydrogen electrode one would calculate under the Rockwood definition is sometimes fortuitously close to the value one would obtain under the Trasatti definition. This near-agreement in the numerical value depends on the choice of ambient temperature and standard states, and is the result of the near-cancellation of certain terms in the expressions. For example, if a standard state of one atmosphere ideal gas is chosen for the electron gas then the cancellation of terms occurs at a temperature of 296 K, and the two definitions give an equal numerical result. At 298.15 K a near-cancellation of terms would apply and the two approaches would produce nearly the same numerical values. However, there is no fundamental significance to this near agreement because it depends on arbitrary choices, such as temperature and definitions of standard states.

See also


  1. ^ IUPAC Gold Book - absolute electrode potential
  2. ^ Sergio Trasatti, "The Absolute Electrode Potential: an Explanatory Note (Recommendations 1986)", International Union of Pure and Applied Chemistry, Pure & AppL Chem., Vol. 58, No. 7, pp. 955–66, 1986. (pdf)
  3. ^ Alan L. Rockwood, "Absolute half-cell thermodynamics: Electrode potential", Physical Review A, Vol 33, No. 1, pp. 554–59, 1986.
  4. ^ Alan L. Rockwood, "Absolute half-cell entropy", Physical Review A, vol. 36, No. 3, pp. 1525–26, 1987.
  5. ^ Zheng Fang, Shaofen Wang, Zhenghua Zhang, and Guanzhou Qiu, "The electrochemical Peltier heat of the standard hydrogen electrode reaction", Thermochimica Acta, Vol. 473, pp. 40–44, 2008.
This article was sourced from Creative Commons Attribution-ShareAlike License; additional terms may apply. World Heritage Encyclopedia content is assembled from numerous content providers, Open Access Publishing, and in compliance with The Fair Access to Science and Technology Research Act (FASTR), Wikimedia Foundation, Inc., Public Library of Science, The Encyclopedia of Life, Open Book Publishers (OBP), PubMed, U.S. National Library of Medicine, National Center for Biotechnology Information, U.S. National Library of Medicine, National Institutes of Health (NIH), U.S. Department of Health & Human Services, and, which sources content from all federal, state, local, tribal, and territorial government publication portals (.gov, .mil, .edu). Funding for and content contributors is made possible from the U.S. Congress, E-Government Act of 2002.
Crowd sourced content that is contributed to World Heritage Encyclopedia is peer reviewed and edited by our editorial staff to ensure quality scholarly research articles.
By using this site, you agree to the Terms of Use and Privacy Policy. World Heritage Encyclopedia™ is a registered trademark of the World Public Library Association, a non-profit organization.

Copyright © World Library Foundation. All rights reserved. eBooks from Project Gutenberg are sponsored by the World Library Foundation,
a 501c(4) Member's Support Non-Profit Organization, and is NOT affiliated with any governmental agency or department.