Melting of the Earth's lithospheric mantle inferred from protactinium– thorium–uranium isotopic data

Abstract

The processes responsible for the generation of partial melt in the Earth's lithospheric mantle and the movement of this melt to the Earth's surface remain enigmatic, owing to the perceived difficulties in generating large-degree partial melts at depth and in transporting small-degree melts through a static lithosphere¹. Here we present a method of placing constraints on melting in the lithospheric mantle using ²³¹Pa– ²³⁵U data obtained from continental basalts in the southwestern United States and Mexico. Combined with ²³⁰Th–²³⁸U data^2,3, the ²³¹Pa–²³⁵U data allow us to constrain the source mineralogy and thus the depth of melting of these basalts. Our analysis indicates that it is possible to transport small melt fractions—of the order of 0.1%—through the lithosphere, as might result from the coalescence of melt by compaction⁴ owing to melting-induced deformation⁵. The large observed ²³¹Pa excesses require that the timescale of melt generation and transport within the lithosphere is small compared to the half-life of ²³¹Pa ( ∼ 32.7 kyr). The ²³¹Pa– ²³⁰Th data also constrain the thorium and uranium distribution coefficients for clinopyroxene in the source regions of these basalts to be within 2% of one another, indicating that in this setting ²³⁰Th excesses are not expected during melting at depths shallower than 85 km.