Neoproterozoic low-T/P metamorphism in the Yangtze Block manifests a long-lived subduction girdle around Rodinia

Identifying long-lived subduction at the periphery of supercontinents provides insights into the processes of block assembly and dispersal within the supercontinent cycle. The Yangtze Block of South China stands as a key component during the transition from Rodinia to Gondwana, characterized by active tectono-magmatic processes throughout the early to middle Neoproterozoic. However, the lack of metamorphic records associated with accretionary orogenesis results in ambiguity about the tectonic regime and its evolution in Rodinia during this period. Here, we present evidence of low-temperature/pressure ratio (low-T/P) metamorphism in phengite-bearing orthogneisses from the western margin of the Yangtze Block (WYB). Through petrographic investigations and zircon U–Pb–Hf–O isotopic analysis in core and rim domains, we identify two distinct metamorphic rock types, with protolith ages of 1419 ± 19 Ma and 831 ± 9 Ma. Both rock types record metamorphism at ca. 830–820 Ma, accompanied by infiltration of externally-derived melts with high-δ18O and unradiogenic Hf isotopes. Our phase equilibria modeling, combined with mineral thermometry and Si-in-phengite content, shows peak metamorphic conditions of ∼550 °C and ∼8.2–8.6 kbar, corresponding to a cold geothermal gradient (19.0–20.5 °C/km). The low-T/P metamorphism is interpreted to occur either in a subduction zone accretionary wedge or in an overriding forearc continental crust, providing robust evidence for Neoproterozoic orogenesis of the WYB within a subduction framework. Based on petrological, isotopic, and paleomagnetic data, we conclude that the WYB represents part of a long-lived subduction girdle (at least ca. 970–750 Ma) at the periphery of Rodinia. Since the early stage of Rodinia breakup, this girdle was involved in alternating advance and retreat accretionary orogenesis as the Yangtze Block continuously drifted away from a mantle upwelling toward the degree-2 girdle of mantle downwelling. Our study provides a snapshot of the evolution of a complete long-lived circum-Rodinian subduction girdle during the transition from Rodinia to Gondwana.