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Long magma residence times at an island arc volcano (Soufriere, St. Vincent) in the Lesser Antilles: evidence from 238U-230Th isochron dating.

Research output: Contribution to journalJournal article


Journal publication date07/1998
JournalEarth and Planetary Science Letters
Number of pages15
Original languageEnglish


High-precision (TIMS) measurements of U and Th isotope concentrations have been determined on whole rocks and mineral separates from Soufriere volcano on St. Vincent in the Lesser Antilles island arc. The whole rocks display relatively constant U/Th ratios (0.5), and are characterised by excess 238U relative to 230Th which is attributed to the addition of U-rich fluids from the subducting slab to the mantle source of the magmas. Mineral isochrons for four recently erupted (<4 ka) rocks yield ages of 46–77 ka and the combined data have an age of 58±7 ka with an initial (230Th/230Th) ratio of 1.05. Mixing of young magmas, or magma–cumulate mixing, are unlikely to be responsible for these isochronous relationships. Contamination of young, phenocrystic magmas with previously crystallised magma could produce the isochrons, in which case the ages provide maximum and minimum ages, respectively, for these two components. However, no lavas with (230Th/230Th) ratios of 1.054 have been found and there is no petrographic evidence for mixing or phenocryst–magma disequilibrium. Our preferred interpretation is that the isochrons reflect long magma residence times within the arc crust. Following initial crystallisation, due to heat loss to the wall rocks, the magmas were maintained at a temperature close to their liquidus while 230Th-ingrowth occurred in both the magma and the crystals. Maintenance of a relatively constant temperature requires good insulation by cumulate layers and probably heating from below by influxes of fresh magma which either did not mix with the resident magma or else had an essentially indistinguishable composition. Subtraction of the residence times from the 90 ka inferred to have elapsed since fluid addition to the mantle wedge leaves 30 ka for transfer through the wedge. Long residence times may typify more evolved lavas that develop in thicker arc crust whereas tholeiitic arc lavas are inferred to have trivial crustal residence times but similar transfer times through the mantle wedge.