Predicting the partial melting conditions that generate Li-rich peraluminous melts is of major economic and societal importance. However, existing models disagree on the optimal conditions (e. g. pressure, temperature, protolith) and, consequently, on targets for exploration. A key source of divergence in model outcomes lies in the choices of partition coefficients used to describe lithium distribution between minerals and melt (DLiᵐineral/melt). Here, we use thermodynamic modelling to simulate isobaric stepwise partial melting of a global compilation of pelite compositions, at crustal pressures and considering variable water saturation and melt extraction thresholds, to calculate melt lithium enrichment predicted by four recently published DLiᵐineral/melt sets. Our results quantify the conditions that maximise lithium enrichment. Depending on DLiᵐineral/melt choices, the predicted optimal conditions range from high-pressure, low-temperature melting of wacke-like compositions, to intermediate-pressure, high-temperature melting of both wacke- and shale-like compositions, or in some cases show limited sensitivity to these parameters. Among these scenarios, the intermediate-pressure, high-temperature melting regimes (associated with biotite breakdown) are most consistent with existing geological and geochemical evidence from lithium-rich granite and pegmatites. Such behaviour is produced when lithium is treated as strongly compatible in biotite relative to other minerals, such as is thought to be the case in fluorinated biotite. Moving forward, pressure-, temperature-, and composition-dependent lithium partitioning models—such as recently developed for biotite—will be crucial to accurately evaluate Li behaviour in anatectic systems.
Owen Weller (Sat,) studied this question.