Even long after the end of volcanic activity, the background geotherma
l flux of Mururoa atoll (French Polynesia) maintains fluid convection.
We present evidences that interstitial water is continuously renewed
in the carbonate platform, as well as in the volcanic basement. In the
carbonate rocks, the presence of a karst system allows convective flu
xes high enough for the thermal equilibration of the formation with th
e ocean around. On the contrary, convection in the volcanic basement i
s, in most places, too slow to cause a measurable disturbance of tempe
rature profiles. Thermal convection models indicate that the average p
ermeability of the volcanic basement cannot be more than a few 10 mD (
10(-14) m(2)), implying a residence time of more than 10,000 years. Th
e concentration of Sr in porewaters is used as an indicator of the roc
k/water ratio and of the residence time of the fluid. Considering the
measured permeabilities and the estimated rates of reaction, residence
times of more than 1 My, corresponding to average permeabilities of l
ess than 10(-16) m(2), are unlikely in the studied upper kilometer of
the volcano. However, the extrapolation of the rates of dissolution fo
r basaltic glass measured in the laboratory to in situ conditions appa
rently leads to overestimate the rates of reaction. Chemically reactiv
e surface area per volume of fluid is a critical parameter in this ext
rapolation and its value is dependent on the method used to measure it
. Although it may not be the only explanation, the discrepancies can b
e caused by the presence of clays in conduits for fluid flow and as a
replacement product of glass. Comparing our results with studies of Qu
aternary basalts in Iceland, the 10 Ma alteration history of the Murur
oa basalt results in a decrease of the permeability of the aquifers by
several orders of magnitude, but does not cause a large change of the
chemically reactive surface area.