Corrosion Science Updated June 22, 2026 16 min read

Pourbaix Diagram Explained: E-pH Diagrams for Corrosion Engineering

The Pourbaix diagram is the foundational thermodynamic tool for predicting which phase – dissolved metal ion, solid oxide, or metallic element – is stable for a given metal-water system at a chosen potential and pH. This article explains how E-pH diagrams are constructed from the Nernst equation, how to interpret the corrosion, passivation, and immunity domains, and how the iron, aluminum, and copper diagrams differ in ways that explain real-world corrosion behavior.

Key Takeaways

  • A Pourbaix diagram plots thermodynamically stable phases of a metal-water system across potential (E, vertical axis) and pH (horizontal axis) at fixed temperature.
  • Three domains define behavior: corrosion (dissolved ion stable), passivation (solid oxide/hydroxide stable), and immunity (metallic state stable).
  • Pourbaix diagrams are purely thermodynamic – they show what is possible, not how fast it happens; kinetics determine actual corrosion rate.
  • Diagram boundaries are calculated from the Nernst equation, with pH-dependent reactions producing sloped lines and pH-independent reactions producing horizontal lines.
  • The water stability region is bounded by the hydrogen evolution line (below) and oxygen evolution line (above), both shown as dashed reference lines.
  • Practical use includes selecting cathodic protection target potentials, evaluating pH-control strategies, and explaining amphoteric behavior in metals such as aluminum.
Simplified Pourbaix Diagram: Fe-H2O System, 25°C pH Potential, E (V vs SHE) 0 7 14 +1.0 0 -1.0 Corrosion Fe2+ stable Passivation Fe2O3 / Fe3O4 stable Corrosion HFeO2- stable Immunity Fe(metal) stable O2 / H2O line H2O / H2 line © metallurgyzone.com
Figure 1. Simplified Pourbaix diagram for iron in water at 25°C, showing the immunity domain (metallic Fe stable, green), the corrosion domains (Fe2+ at low pH and HFeO2- at high pH, red), and the intervening passivation domain where Fe2O3/Fe3O4 oxides are thermodynamically stable (orange). Dashed lines mark the thermodynamic stability limits of water. © metallurgyzone.com

Thermodynamic Basis: The Nernst Equation

Every line on a Pourbaix diagram is the locus of potential and pH values at which two species – on either side of a specific half-reaction – have equal thermodynamic stability, i.e., equal Gibbs free energy. These equilibrium lines are calculated from the Nernst equation. For background on the free energy criterion underlying this approach, see our article on corrosion mechanisms.

General Nernst relation:
  E = E0 - (RT / nF) ln Q

At 25C, converting to base-10 log and grouping constants:
  E = E0 - (0.0592 / n) log Q

For a reaction releasing/consuming H+ ions, Q contains [H+],
so the line takes the form:
  E = E0 - (a) x pH       (sloped line, a = 0.0592 x m / n)
       where m = stoichiometric coefficient of H+ in the reaction

For reactions with NO H+ involvement (pure electron transfer):
  E = E0                  (horizontal line, independent of pH)

For reactions with H+ but NO electron transfer (pure acid-base
equilibria, e.g. solubility boundaries):
  pH = constant            (vertical line, independent of E)

This is why Pourbaix diagrams characteristically show three line types: horizontal lines for purely electrochemical (redox) equilibria, vertical lines for purely chemical (acid-base or solubility) equilibria, and sloped lines for reactions that involve both electron transfer and H+ or OH- exchange.

The Three Domains

Immunity

In the immunity domain, the metallic element itself is the thermodynamically stable form. No driving force exists for oxidation regardless of pH, so corrosion cannot occur thermodynamically. Cathodic protection systems are designed specifically to depress the metal’s potential into this domain.

Corrosion

In the corrosion domain, a soluble ionic species (Fe2+, Al3+, Cu2+, or similar) is the stable form, meaning the metal thermodynamically tends to dissolve. Whether this translates into a significant practical corrosion rate depends on the kinetics of the dissolution reaction, which the diagram itself does not address. This is directly relevant to localized attack discussed in our pitting corrosion coverage, since a metal can be in the corrosion domain globally while a stable passive film still locally protects most of the surface.

Passivation

In the passivation domain, a solid oxide or hydroxide compound is the thermodynamically stable phase. If this solid forms as a continuous, adherent, low-porosity film, it can dramatically reduce the practical corrosion rate even though the underlying driving force for oxidation remains present – this is the thermodynamic basis for the passive behavior of stainless steels, aluminum, and titanium. The diagram cannot tell you whether the film will actually be protective; that depends on film structure, chloride content, and mechanical integrity, topics covered further in our crevice vs pitting corrosion comparison.

Common Misreading: Thermodynamics Is Not Kinetics

The single most common misuse of Pourbaix diagrams is treating the passivation domain as a guarantee of low corrosion rate, or the corrosion domain as a guarantee of high corrosion rate. The diagram tells you only which phase has the lowest free energy; actual corrosion rate is controlled by reaction kinetics, mass transport, and the mechanical/chemical integrity of any film that forms, none of which appear on the diagram.

Comparing Diagrams Across Metals

MetalPassivation pH range (approx., 25°C)Key oxide phasePractical implication
Iron~9.5 to 12.5 (narrow, near-neutral attack possible)Fe2O3, Fe3O4, Fe(OH)2Corrodes in both acidic and mildly alkaline water; passive only in a relatively narrow alkaline band
Aluminum~4 to 8.5 (amphoteric)Al2O3 / Al(OH)3Corrodes rapidly in both strong acid and strong alkali; passive film stable only near neutral pH
Copper~7 to 13.5 (broad, but ion stability depends on potential)Cu2O, CuO, Cu(OH)2Relatively noble; immunity domain extends to mildly oxidizing conditions near neutral pH
TitaniumVery broad (~2 to 12)TiO2Exceptionally stable passive film across almost the entire practical pH range, explaining its corrosion resistance
Passivation Domain Width Comparison (25°C, fixed potential) pH (0 to 14) 0 7 14 Iron Aluminum Titanium Corrosion domain Passivation (narrow/moderate) Passivation (broad) © metallurgyzone.com
Figure 2. Relative width of the passivation domain across pH for iron, aluminum, and titanium at a representative oxidizing potential, illustrating why titanium remains passive across nearly the full pH range while aluminum’s amphoteric oxide restricts passivity to a narrow near-neutral band. © metallurgyzone.com

Practical Engineering Applications

Cathodic Protection Target Selection

Cathodic protection design uses the immunity domain boundary as the thermodynamic target potential; impressed current or sacrificial anode systems are sized to depress the structure’s potential below this line across the entire protected area, though practical protection criteria (such as the -850 mV CSE criterion for buried steel) include additional margin beyond the strict thermodynamic boundary.

Water Chemistry and pH Control

Boiler and cooling water treatment programs frequently target a pH range that places carbon steel comfortably within its passivation domain, which is the thermodynamic basis for the alkaline pH control commonly specified in closed-loop systems, complementing the inhibitor chemistries discussed in our corrosion inhibitors article.

Explaining Amphoteric Metal Behavior

The narrow passivation band for aluminum directly explains practical observations such as rapid attack of aluminum components by strongly alkaline cleaning solutions or concrete pore water (pH often above 12.5), even though the same aluminum performs well in neutral atmospheric exposure.

Industrial Significance

Pourbaix diagrams remain a first-pass screening tool in corrosion engineering curricula and failure analysis because they immediately reveal whether an observed corrosion mode is even thermodynamically plausible at the service pH and potential, narrowing the field of credible mechanisms before kinetic and microstructural factors such as those discussed in our HAZ microstructure article are brought in to explain the actual observed rate and morphology.

Frequently Asked Questions

What is a Pourbaix diagram?
A Pourbaix diagram, also called an E-pH diagram, is a thermodynamic equilibrium map that plots the stable phases of a metal-water system as a function of electrochemical potential (E) on the vertical axis and pH on the horizontal axis at a fixed temperature, showing regions of corrosion, passivation, and immunity for that metal.
What are the three main domains shown on a Pourbaix diagram?
The three main domains are corrosion, where soluble metal ions are the thermodynamically stable species; passivation, where a stable solid oxide or hydroxide film forms on the metal surface; and immunity, where the metal itself in its metallic state is thermodynamically stable and no corrosion can occur regardless of kinetics.
Does a Pourbaix diagram predict corrosion rate?
No. A Pourbaix diagram is a purely thermodynamic construction based on equilibrium potentials and contains no kinetic information, so it indicates only whether corrosion is thermodynamically possible in a given domain, not how fast it will proceed. A metal can sit in the corrosion domain yet corrode extremely slowly due to kinetic barriers such as a protective but thermodynamically metastable film.
How is the Nernst equation used to construct a Pourbaix diagram?
Each line on a Pourbaix diagram represents the equilibrium condition for a specific reaction between two stable species, calculated from the Nernst equation, E = E0 – (RT/nF) ln Q, where E0 is the standard electrode potential, R is the gas constant, T is temperature, n is the number of electrons transferred, F is the Faraday constant, and Q is the reaction quotient involving activities of dissolved species and, for reactions involving H+, the pH.
Why does the passivation domain not guarantee corrosion protection in practice?
The passivation domain only indicates that a solid oxide or hydroxide is thermodynamically stable; it says nothing about whether that film is continuous, adherent, or resistant to chemical or mechanical breakdown by chloride ions, erosion, or stress. A thermodynamically stable passive film can still suffer localized breakdown leading to pitting or crevice corrosion in practice.
What are the two diagonal dashed lines typically shown on a Pourbaix diagram?
The two diagonal dashed lines represent the thermodynamic stability limits of water itself: the upper line corresponds to oxygen evolution (2H2O -> O2 + 4H+ + 4e-) and the lower line corresponds to hydrogen evolution (2H+ + 2e- -> H2). Together they bound the region where water is thermodynamically stable against electrolytic decomposition.
How does temperature affect a Pourbaix diagram?
Pourbaix diagrams are calculated for a specific temperature because both the equilibrium potentials and the water stability lines are temperature dependent; raising temperature generally shifts domain boundaries and can shrink or eliminate passivation domains for some metals, which is why diagrams calculated at 25 degrees Celsius may not apply directly to elevated-temperature service such as boiler or reactor environments.
Why does aluminum show a narrow passivation domain centered near neutral pH?
Aluminum oxide is amphoteric, meaning it dissolves both in strongly acidic conditions (forming Al3+) and strongly alkaline conditions (forming aluminate, AlO2-), so its passive oxide film is thermodynamically stable only within a narrow intermediate pH band, typically from about pH 4 to pH 8.5, explaining why aluminum corrodes readily in both strong acids and strong alkalis.
Can a Pourbaix diagram be used to select cathodic protection or inhibitor strategy?
Yes. Cathodic protection works by shifting the metal’s potential downward into the immunity domain, which can be visualized directly on the diagram, while pH-adjusting or passivating inhibitor treatments work by shifting the operating point into the passivation domain; the diagram provides the thermodynamic target even though kinetic and engineering verification is still required.
What is the difference between a Pourbaix diagram and a polarization (Evans) diagram?
A Pourbaix diagram is a thermodynamic equilibrium map over a potential-pH plane showing stable phases with no time or rate information, while a polarization diagram plots current density against potential at fixed pH and composition to show the kinetics of the anodic and cathodic reactions and predict actual corrosion rate and corrosion potential through their intersection.

Recommended Reference Materials

Corrosion Engineering: Principles and Practice

Graduate-level corrosion electrochemistry text with detailed treatment of Pourbaix and polarization diagrams.

View on Amazon

Atlas of Electrochemical Equilibria in Aqueous Solutions

The original Pourbaix reference atlas covering E-pH diagrams for the full range of engineering metals.

View on Amazon

Electrochemical Methods: Fundamentals and Applications

Core reference on electrochemical theory underpinning Nernst equation derivations and equilibrium diagrams.

View on Amazon

Uhlig’s Corrosion Handbook

Classic reference text covering thermodynamic and kinetic aspects of aqueous corrosion across metals.

View on Amazon

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