Magma Redox Geochemistry. Группа авторов

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Название Magma Redox Geochemistry
Автор произведения Группа авторов
Жанр Физика
Серия
Издательство Физика
Год выпуска 0
isbn 9781119473244



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which participates with half‐reaction 1.7 in giving Reaction 1.3 and does not involve explicitly the water solvent.

      4 vertical lines, representing no change of oxidation state but only acid–base reactions (a sole exchange of protons for aqueous solutions), such as(1.23) with the boundary plotted at the pH value for which Q23 = K23 with aFe2O3(s) = (aFe3+)2 = 1 (and also aH2O = 1).

Schematic illustration of the E-pH (Pourbaix) diagram for the Fe-S-H2O system at 25 degrees Celsius at 1 bar total pressure and for total dissolved sulfur activities of 0.1 (panel a) and 10–6 (panel b).

      Modifed from Vaughan (2005).

      Basically, E‐pH diagrams demonstrate that breaking of a redox reaction into half‐reactions is one of the most powerful ideas in redox chemistry, which allows relating the electron transfer to the charge transfer associated with the speciation state and the acid–base behavior of the solvent. Superimposing E‐pH diagrams allows a fast recognition of the existing chemical mechanism occurring in an electrolyte medium. For example, Figure 1.2 on the Fe‐H‐O‐S system can be seen as the result of the superposition of stability diagrams for H‐O‐S and Fe‐O‐H system. The resulting diagram in Figure 1.2 shows that the pyrite–magnetite boundary has a negative slope due to half‐reaction:

      (1.24)equation

      but also a positive slope well visible in Figure 1.2b due to sulfur reduction and dissolution in water as HS:

      (1.26)equation

      which has a negative slope of –0.0295pH because the number of exchanged electrons is double than protons.

      These concepts can then be transferred to other solvents in which ligand–metal exchanges lead to a different speciation state and are governed by a different notion of basicity, i.e. oxobasicity, such that (see Moretti, 2020 and references therein):

      which can be also related to redox exchanges via the normal oxygen electrode (Equation 1.6), in the same way the normal hydrogen electrode (Reaction 1.7) can be put in relation with the Bronsted‐Lowry definition of acid–base behaviour in aqueous solutions (see Moretti, 2020):

      (1.28)equation

Schematic illustration of limit of equilibrium potential-p02– graphs in molten alkali carbonates and sulfates, at 600 degrees Celsius.

      (modified from Trémillon, 1974).

      The upper stability limit is related to the O–II/O2(g) redox system (Reaction 1.6), i.e., to the oxidation of CO32– and SO42– anions: