Magma to mud to magma: Rapid crustal recycling by Permian granite magmatism near the eastern Gondwana margin

Early Permian (Cisuralian) S-type monzogranites of the Bundarra Supersuite, New England Orogen (NEO), eastern Australia, have chemical and isotopic compositions indicative of their being derived from young, weathered, volcanogenic sedimentary source rocks. High δ18Ozrn values of zircon precipitated from the melt phase of the magma (ca. 11.5‰) confirm that the previously measured high granite whole-rock values (δ18OWR) are a primary magmatic feature. Abundant inherited detrital zircon cores with a range of dates (360-300 Ma) and distinctly lower δ18Ozrn values (ca. 5-10‰) were derived from mostly young (Carboniferous) volcanogenic source rocks that became less primitive and more isotopically diverse with time. The age difference between the youngest inherited zircon population and the earliest zircon growth during magma genesis is about 15 Ma. An arc-related volcanogenic sedimentary pile built up over about 50 Ma was weathered, buried, and partially melted, producing voluminous peraluminous magmas within no more than ca. 15 Ma of the youngest source sediment being deposited. The time interval between the initiation of melting and post-emplacement magma crystallization was about 5 Ma. The S-type Bundarra Supersuite in the NEO is a rare case in which the entire geologic cycle has been captured by zircon. Recognizing this is uniquely possible because of the relatively simple populations of inherited and newly-grown zircon, and their distinctive oxygen isotopic compositions.

► Inherited, early and late magmatic zircon in granite have been clearly distinguished. ► Partial melting started only 15 Ma after volcanism, the youngest source sediment. ► Ιnterval between initial melting and granite magma mobilization was a further 5 Ma. ► Igneous rocks can be weathered, buried and remelted rapidly: recycling in < 15 Ma.