which would contribute to thegenera

which would contribute to the
generation of hydrogen as well. However, since Fe+3 in talc is not
well documented and no thermodynamic data are available we have
not considered Fe+3 in talc in our calculations. Given that the concentrations
of the bulk Fe in talc are low compared with serpentine and
brucite, the effect of Fe+3 in talc is likely to be negligible. Serpentine
in abyssal serpentinites is commonly chrysotile or lizardite. Antigorite
is commonly found in alpine-type serpentinites but rare in abyssal
serpentinites. As pointed out by Evans (2004) and Frost and Beard
(2007) the differences between thermodynamic properties of chrysotile
and lizardite are trivial and therefore we chose chrysotile to represent
the Mg-endmember of serpentine. Metastable equilibria were
accounted for by suppressing the formation of aragonite, calcite, dolomite,
monticellite, magnesite, antigorite, hydroxyltopaz, huntite,
wüstite, grossular and andradite. While calcite has been found in abyssal
serpentinite, either as vein fillings indicative of mixing processes involving
hydrothermal fluid and seawater, or as a replacement mineral
in mesh-textured serpentinite indicative of a metasomatic process,
most serpentinite samples are calcite-free. To illustrate the principal
regulatory influences of protolith composition on serpentinization we
decided not to allow carbonate precipitation. Moreover, we suppressed
the reduction of sulfate and carbon by H2(aq)