Trondhjemites from the Qianxi Complex, North China Craton: Implications for Neoarchean crustal growth

Abstract

The TTG (tonalite‐trondhjemite‐granodiorite) rock suites are major building blocks of the Archean continental crust and their timing of formation and petrogenetic evolution are important keys to understanding the growth of continents in the Early Earth. Here we investigate trondhjemites from the Qiangxi Complex in the North China Craton and present petrological, geochemical and zircon U–Pb, REE and Lu–Hf data to understand the timing of their formation and petrogenetic history. The trondhjemites in our study belong to typical Archean Na‐rich TTG rocks and their geochemical features are similar to high‐Al TTG rocks. The geochemical characteristics of these rocks and the associated amphibolite indicate derivation from a subduction‐related hydrous basalt. The magmatic zircon grains from the trondhjemite samples show a peak 207Pb/206Pb age around 2,515 Ma. Magmatic zircon in the associated amphibolite also shows a similar age representing the timing of the protolith formation. Both the trondhjemites and amphibolite also contain metamorphic zircon grains which constrain the timing of metamorphism as 2,451–2,490 Ma, suggesting high‐grade metamorphism closely following the magmatism, associated with the assembly of the microblocks in the NCC. The geochemical characteristics and zircon age data presented in this study, in conjunction with those in previous studies from the Qiangxi Complex, suggest subduction‐related arc building occurred dominantly during 2.6–2.5 Ga. The Lu‐Hf isotope data from zircon grains in the trondhjemite and amphibolite samples of this study show dominantly positive εHf(t) values, indicating that the protolith magma was derived from juvenile components or depleted mantle. Our new results in conjunction with the data reported in earlier studies indicate a major crust‐building event through multiple magmatism during Neoarchean. The depleted mantle ages (TDM) of zircon in our samples range from 2,857 Ma to 2,605 Ma indicating that active subduction might have initiated in the late Mesoarchean, with the peak of magmatism during 2.6–2.5 Ga, followed by metamorphism at ca. 2.45–2.49 Ga.