Young (< 5 kyr) olivine- and clinopyroxene-phyric
ne-hawaiites from Mounts Gambier and Schank in the Newer Volcanic Province in South Australia have been analysed for major and trace elements as well as for Sr and Nd isotopes and
238U–
230Th disequilibria in order to constrain the mantle melting processes responsible for their origin. The rocks are relatively primitive (6.9–9.1 % MgO), incompatible trace element-enriched alkali basalts with
87Sr/
86Sr = 0.70398–0.70415 and
143Nd/
144Nd = 0.51280–0.51271. Trace element modelling suggests that they reflect 3–6 % partial melting in the presence of 2–8 % residual garnet. Trends towards low K/K
are accompanied by decreasing
87Sr/
86Sr and provide evidence for the involvement of hydrous phases during melting.
230Th excesses of 12–57 % cannot be simulated by batch melting of the lithosphere and instead require dynamic melting models. It is argued that the distinction between continental basalts bearing significant U–Th disequilibria and those in secular equilibrium reflects dynamic melting in upwelling asthenosphere, rather than static batch melting within the lithosphere or the presence or absence of residual garnet. Upwelling rates are estimated at
1.5 cm/yr. A subdued, localised topographic uplift associated with the magmatism suggests that any upwelling is more likely associated with a secondary mode localised to the upper mantle, rather than a broad
zone of deeply-sourced (plume) upwelling. Upper mantle, ‘edge-driven’ convection is consistent with seismic tomographic and anisotropy studies that imply rapid differential motion of variable
thickness Australian lithosphere and the underlying asthenosphere. In this scenario, melting is linked to a significant contribution from hydrous mantle that is envisaged as resulting either from convective
entrainment of lithosphere along the trailing edge of a lithospheric keel, or inherited variability in the asthenosphere.