Rb/Sr isotopic and compositional retentivity of muscovite during deformation

Permian metapegmatite muscovite from the Upper-Austroalpine Matsch Unit in Southern Tyrol (Italy) was investigated regarding its Rb/Sr and compositional retentivity during Cretaceous Upper-greenschist facies deformation. The data imply that microstructurally relic Permian magmatic muscovite largely maintained its major and trace element compositions during deformation, whereas the Rb/Sr geochronometer is strongly affected by a net loss of Sr. Lower Sr concentrations of muscovite correlate with higher (87)Rb/(86)Sr and (87)Sr/(86)Sr ratios. In most samples, the muscovite grain size- and magnetic-fractions with the lowest (87)Rb/(86)Sr and (87)Sr/(86)Sr ratios preserve a Permo-Triassic muscovite–whole rock Rb/Sr apparent age interpreted as to reflect formation during or cooling after pegmatite emplacement. Contrastingly, muscovite fractions with higher (87)Rb/(86)Sr and (87)Sr/(86)Sr ratios are arranged along a roughly linear array with a positive correlation of the (87)Rb/(86)Sr and (87)Sr/(86)Sr ratios in the (87)Rb/(86)Sr vs (87)Sr/(86)Sr space. They yield successively lower muscovite–whole rock Rb/Sr apparent ages. We explain the variations in the Rb/Sr isotopic character of microstructurally relic muscovite by a, presumably deformation-related, loss of Sr during the Cretaceous event. Contemporaneously, only very limited amounts of isotopically different Sr from the matrix reservoir might possibly have entered the muscovite. Consequently, the Rb/Sr of the relic muscovite is affected by a net loss of Sr. The results imply that at temperatures of < 500 °C, deformation is supposed to be the predominant factor in controlling the Rb/Sr geochronometer of relic muscovite, by significantly reducing the characteristic length scale for volume diffusion. However, variations of the major and trace element compositions within Permian relic muscovite are interpreted to rather reflect primary compositional instead of deformation-related variations.