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| [[Image:Pourbaix Diagram of Iron.svg|thumb|Pourbaix diagram of iron.<ref>[http://people.bath.ac.uk/chsataj/CHEY0016%20Lecture%2015.htm University of Bath] & [http://www.wou.edu/las/physci/ch412/pourbaix.htm Western Oregon University]</ref>
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| In [[chemistry]], a '''Pourbaix diagram''', also known as a '''potential/pH diagram''', '''E<sub>H</sub>-pH diagram''' or a '''pE/pH diagram''', maps out possible stable ([[Chemical equilibrium|equilibrium]]) phases of an aqueous electrochemical system. Predominant ion boundaries are represented by lines. As such a Pourbaix diagram can be read much like a standard [[phase diagram]] with a different set of axes. But like phase diagrams, they do not allow for [[reaction rate]] or kinetic effects.
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| The diagrams are named after [[Marcel Pourbaix]] (1904–1998), the [[Russia|Russian]]-born, Belgian [[Chemistry|chemist]] who invented them.
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| ==Diagram==
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| [[Image:Uranium pourdaix diagram in water.png|thumb|right|240px|The Pourbaix diagram for uranium in a non-complexing aqueous medium (e.g. [[perchloric acid]] / sodium hydroxide).<ref name="medusa"/>]]
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| [[Image:Uranium pourdiax diagram in carbonate media.png|thumb|right|240px|The Pourbaix diagram for uranium in carbonate solution. The dashed green lines show the stability limits of water in the system. <ref name="medusa">. Ignasi Puigdomenech, ''Hydra/Medusa Chemical Equilibrium Database and Plotting Software'' (2004) KTH Royal Institute of Technology, freely downloadable software at [http://www.kemi.kth.se/medusa/]</ref>]]
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| Pourbaix diagrams are also known as E<sub>H</sub>-pH diagrams due to the labeling of the two axes. The vertical axis is labeled E<sub>H</sub> for the [[Reduction potential|voltage potential]] with respect to the [[standard hydrogen electrode]] (SHE) as calculated by the [[Nernst equation]]. The "H" stands for hydrogen, although other standards may be used, and they are for room temperature only.
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| :<math>E_H = E^0 - \frac{0.0592}{n} \log\frac{[C]^c[D]^d}{[A]^a[B]^b} \ \{ V \} </math>
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| The horizontal axis is labeled [[pH]] for the -log function of the H<sup>+</sup> ion activity.
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| :<math>\mathrm{pH} = - \log_{10}(a_{\textrm{H}^+}) = \log_{10}\left(\frac{1}{a_{\textrm{H}^+}}\right)</math>
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| The lines in the Pourbaix diagram show the equilibrium conditions, that is, where the activities are equal, for the species on each side of that line. On either side of the line, one form of the species will instead be said to be predominant.<ref name="Environmental Chemistry (vanLoon)" />
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| In order to draw the position of the lines with the Nernst equation, the activity of the chemical species at equilibrium must be defined. Usually, the activity of a species is approximated as equal to the concentration (for soluble species) or partial pressure (for gases). The same values should be used for all species present in the system.<ref name="Environmental Chemistry (vanLoon)" />
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| For soluble species, the lines are often drawn for concentrations of 1 M or 10<sup>−6</sup> M. Sometimes additional lines are drawn for other concentrations.
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| If the diagram involves the equilibrium between a dissolved species and a gas, the pressure is usually set to P<sup>0</sup> = 1 atm = 101,325 Pa, the minimum pressure required for gas evolution from an aqueous solution at standard conditions.<ref name="Environmental Chemistry (vanLoon)" />
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| While such diagrams can be drawn for any chemical system, it is important to note that the addition of a metal binding agent ([[ligand]]) will often modify the diagram. For instance, [[carbonate]] has a great effect upon the diagram for uranium. (See diagrams at right.) The presence of trace amounts of certain species such as chloride ions can also greatly affect the stability of certain species by destroying passivating layers.
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| In addition, changes in temperature and concentration of solvated ions in solution will shift the equilibrium lines in accordance with the Nernst equation.
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| The diagrams also do not take kinetic effects into account, meaning that species shown as instable might not react to any significant degree in practice.
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| A simplified Pourbaix diagram indicates regions of "Immunity", "Corrosion" and "Passivity", instead of the stable species. They thus give a guide to the stability of a particular metal in a specific environment. Immunity means that the metal is not attacked, while [[corrosion]] shows that general attack will occur. [[Passivation (chemistry)|Passivation]] occurs when the metal forms a stable coating of an oxide or other salt on its surface, the best example being the relative stability of [[aluminium]] because of the [[alumina]] layer formed on its surface when exposed to air.
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| === The stability region of water ===
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| In many cases, the possible conditions in a system are limited by the stability region of water. In the Pourbaix diagram for uranium, the limits of stability of water are marked by the two dashed green lines, and the stability region for water falls between these lines.
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| Under highly reducing conditions (low E<sub>H</sub>/pE) water will be reduced to hydrogen according to<ref name="Environmental Chemistry (vanLoon)" />
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| <math>2H_2O + 2e^- \rightarrow H_2(g) + 2OH^- </math>
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| or
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| <math>2H_3O^+ + 2e^- \rightarrow H_2(g) + 2H_2O </math>
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| Using the Nernst equation, setting E<sup>0</sup> = -0.828 V and the hydrogen gas fugacity (corresponding to activity) at 1, the equation for the lower stability line of water in the Pourbaix diagram will be
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| <math>E_H = - 0.0591*pH \ \{ V \} </math>
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| at standard temperature and pressure. Below this line, water will be reduced to hydrogen, and it will usually not be possible to pass beyond this line as long as there is still water present to be reduced.
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| Correspondingly, under highly oxidizing conditions (high E<sub>H</sub>/pE) water will be oxidized to oxygen gas according to<ref name="Environmental Chemistry (vanLoon)" />
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| <math>6H_2O \rightarrow 4H_3O^+ + O_2(g) + 4e^- </math>
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| Using the Nernst equation as above, but with an E<sup>0</sup> of 1.229 V, gives an upper stability limit of water at
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| <math>E_H = 1.229 V - 0.0591*pH \ \{ V \} </math>
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| at standard temperature and pressure. Above this line, water will be oxidized to form oxygen gas, and it will usually not be possible to pass beyond this line as long as there is still water present to be oxidized.
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| == Uses ==
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| Pourbaix diagrams have several uses, for example in corrosion studies, geology and in environmental studies.
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| === In environmental chemistry ===
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| Pourbaix diagrams are widely used to describe the chemical behaviour of chemical species in the hydrosphere. In these cases, [[Reduction potential|pE]] is used instead of E<sub>H</sub>.<ref name="Environmental Chemistry (vanLoon)">{{cite book|last=vanLoon|first=Gary|title=Environmental Chemistry - a global perspective|year=2011|publisher=Oxford University Press|isbn=978-0-19-922886-7|pages=235-248|edition=3rd|coauthors=Duffy, Stephen}}</ref>
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| pE is a dimensionless number and can easily be related to E<sub>H</sub> by the equation
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| :<math>pE = \frac{E_{H}}{0.0591 V}</math>
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| pE values in environmental chemistry ranges from -12 to 25, since at low or high potentials water will be reduced or oxidized, respectively. In environmental applications, the concentration of dissolved species is usually set to a value between 10<sup>−2</sup> M and 10<sup>−5</sup> M for the creation of the equilibrium lines.
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| ==See also==
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| * [[Ellingham diagram]]
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| * [[Latimer diagram]]
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| * [[Frost diagram]]
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| * [[Ionic partition diagram]]
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| ==References==
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| {{reflist}}
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| * ''Brookins, D. G.'', Eh-pH Diagrams for Geochemistry. 1988, Springer-Verlag, ISBN 0-387-18485-6
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| * ''Denny A. Jones'', Principles and Prevention of Corrosion, 2nd edition, 1996, Prentice Hall, Upper Saddle River, NJ. ISBN 0-13-359993-0 Page 50-52
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| * ''Pourbaix, M.'', Atlas of electrochemical equilibria in aqueous solutions. 2d English ed. 1974, Houston, Tex.: National Association of Corrosion Engineers.
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| ==External links==
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| {{commons category|Pourbaix diagrams}}
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| * [http://www.corrosion-doctors.org/Biographies/PourbaixBio.htm Marcel Pourbaix] — Corrosion Doctors
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| * [http://www.doitpoms.ac.uk/tlplib/pourbaix/index.php DoITPoMS Teaching and Learning Package- "The Nernst Equation and Pourbaix Diagrams"]
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| ===Software===
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| * [http://www.eawag.ch/research_e/surf/Researchgroups/sensors_and_analytic/chemeql.html ChemEQL] Free software for calculation of chemical equilibria from [[Eawag]]
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| * [http://www.factsage.com/ FactSage] Commercial thermodynamic databank software, also available in a free [http://www.crct.polymtl.ca/ephweb.php?lang= web application]
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| * [http://www.gwb.com/pourbaix.htm The Geochemist's Workbench] Commercial geochemical modeling software from Aqueous Solutions LLC
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| * [http://www.kth.se/che/medusa/ HYDRA/MEDUSA] Free software for creating chemical equilibrium diagrams from the [[KTH]] Department of Chemistry
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| * [http://www.hsc-chemistry.net/Eh-pH%20Diagrams%20Pourbaix.html HSC Chemistry] Commercial thermochemical calculation software from Outotec Research Oy
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| * [http://www.phreeplot.org/ PhreePlot] Free program for making geochemical plots using the [[USGS]] code [http://wwwbrr.cr.usgs.gov/projects/GWC_coupled/phreeqc/ PHREEQC]
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| * [http://www.thermocalc.se/Corrosion.htm Thermo-Calc Windows] Commercial software for thermodynamic calculations from Thermo-Calc Software
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| [[Category:Electrochemistry]]
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| [[Category:Phase transitions]]
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