The role of metamorphic fluid transport in the Rb-Sr isotopic resetting of shear zones: evidence from Nordre Str�mfjord, West Greenland

Abstract

The Nordre Stromfjord shear zone is about 20 km wide and is exposed for 170 km along strike. It formed under granulite to amphibolite facies conditions as part of the 1,850 Ma-old Nagssugtoqidian orogeny affecting the largely Archean terrain of central West Greenland. We have made Rb-Sr isotope measurements on ca. 130 whole rock samples from the shear zone and have made microprobe analyses of biotite and plagioclase on 40 of them in order to evaluate the effects of shear zone formation on the Rb-Sr isotope system. Seven separate localities were sampled, four of them extensively; large whole rock samples and small, cm-scale thin slices were used in this study. The Rb-Sr isotope systems and the biotite compositions of the large whole rocks show variable degrees of re-equilibration during shear zone formation. Rb-Sr data for the least affected suites still scatter about Archean isochrons and the biotite compositions show wide variations both within and between samples. In other more affected suites, the Rb-Sr system was reset to approximate the age of shear zone formation on the scale of 10's of meters, and the biotite compositions are consistent within individual samples. The most strongly affected suites underwent profound chemical and isotopic changes. Whole rock suites preserve virtually no Rb-Sr isotopic record of their preshear zone history and the biotite compositions of entire suites are very homogeneous. The cm-scale suites of thin slices all show some degree of Proterozoic re-equilibration, although sharp Sr isotopic discontinuities between groups of lithologic layers are preserved. Among the suites of large whole rocks, the observed variations do not correlate with variations in shear strain, size of sampling domain, average Rb/Sr, range of Rb/Sr or ppm Sr. The combined Rb-Sr and microprobe data suggest that the responses are most likely to represent differences in total fluid/rock ratio in a system undergoing significant fluid transport. Our data suggest an uneven distribution of fluid pathways within the shear zone and a strongly preferred direction of fluid flow parallel to lithologic boundaries. Data from previous studies are also consistent with the conclusion that fluid transport is the major agent of Rb-Sr isotopic resetting in shear zones. This conclusion has implications for optimum sampling strategies in Rb-Sr dating of high strain events and for the processes by which Rb-Sr isotopic resetting occurs during regional metamorphism.