THE H2O CONTENT OF BASALT GLASSES FROM SOUTHWEST PACIFIC BACK-ARC BASINS

The H2O content of 35 glasses from Southwest Pacific back-arc basins ( Lau, North Fiji, Woodlark and Manus) have been determined by infrared spectroscopy. On a plot of K2O vs. H2O the glass data define two disti nct trends characterized by different slopes. Trend I, with a slope (K 2O/H2O) of 0-25, can be explained by addition of a subduction-related component with K2O/H2O = 0.25 to a depleted mid-ocean ridge basalt man tle source (N- or D-MORB-like). Trend II, which coincides with the N- to E-MORB compositional spectrum, can be produced by addition of a non -subduction component, possibly an alkaline magma with K2O/H2O approxi mately 1.5, to the same depleted mantle source. The K2O/TiO2 and K/Nb values of E-MORB and back-arc basin basalts (BABB) of Trend II suggest that the enriched component involved in their genesis is not derived from a typical ocean island basalt (OIB, e.g. Hawaiian) mantle source. Our data show that the entire spectrum of BABB compositions can be ex plained by different degrees of mixing of a mantle source of either D- , N- or E-MORB composition with the subduction-related component, char acterized by a K2O/H2O value of 0.25. Different BABB types correlate w ith tectonic setting. Samples from the Trend II are associated with re latively stable spreading ridges, whereas those affected by the subduc tion-related component are always associated with more complex tectoni c settings, or come from young or incipient back-arc basins. Pronounce d E-MORB affinities of mantle sources are demonstrated only for sample s from the Lau, North Fiji and Scotia Sea basins. The most H2O enriche d BABB of Trend I partly overlap in terms of H2O and K2O content and H 2O/TiO2 and K2O/TiO2 values with island arc tholeiites. This suggests involvement of similar subduction-related components in the genesis of these two magma types. Because a larger database is now available, th e K2O/H2O vs. TiO2 tectonic discriminant diagram of Muenow et al. [2] appears to be less useful than when originally proposed. The very low K2O/H2O value (< 0.05) of the H2O-bearing phase involved in boninite g enesis implies that it maybe a fluid derived from the subducted slab. The significantly higher K2O/H2O value (0.25) of the subduction-relate d component involved in petrogenesis of BABB and some arc tholeiites i ndicates that it was a melt, rather than a fluid. This K2O/H2O value ( 0.25) is also of some interest, as the same value occurs in depleted M ORB.