• Changyi BIF is a Paleoproterozoic Superior-type deposit formed in a back-arc basin. • The Fe–O isotopes in the Changyi BIF record redox changes linked to the GOE. • U-Pb ages (∼2.9–2.7 Ga, 2.45 Ga, 2.2 Ga) indicate BIF incorporated magmatic material. • Changyi BIF experienced peak amphibolite-facies metamorphism at ∼785 °C/6.2 kbar. • Whole-rock δ18O values show limited regional isotopic homogenization. The Paleoproterozoic banded iron formation (BIF) at Changyi in the eastern North China Craton is a rare example of a Superior-type BIF in China. However, its genesis, depositional age, and tectonic setting remain poorly constrained and highly debated. In this study, we integrated zircon U–Pb geochronology, whole-rock geochemistry, Fe–O isotopes, and P – T phase equilibrium modeling to systematically constrain the formation age, provenance, and depositional environment of the Changyi BIF. Detrital zircon U–Pb geochronology reveals a provenance derived from both Archean cratonic basement (∼2.9 Ga and ∼2.7 Ga) and Paleoproterozoic magmatic materials (∼2.45 Ga and ∼2.2 Ga). The detrital zircon age spectrum shows a distinct peak at ∼2.45 Ga, providing clear evidence for a major magmatic event of this age in the source region, while the youngest zircon population (2243 Ma) constrains the maximum depositional age of the BIF. The ores are dominated by SiO 2 and total Fe 2 O 3 (TFe 2 O 3 ). The increasing contents of Al 2 O 3 and TiO 2 from Type I to Type III ores indicate progressively enhanced detrital input. The REY distribution patterns are characterized by LREE depletion, positive La, Eu, and Y anomalies, and low ΣREY. Mixing model results indicate that the ore-forming materials were mainly derived from seawater, with minor contributions from high-temperature hydrothermal fluids and continental solutes. Whole-rock δ 18 O values range from 8.8‰ to 10.9‰, with reconstructed original δ 18 O values between 8.8‰ and 12.25‰. The δ 18 O values of different ore types are jointly controlled by mineral proportions and the intensity of metamorphic/fluid processes, with Type III ore exhibiting the lowest δ 18 O values, reflecting fluid–rock exchange and isotopic resetting. However, large-scale isotopic homogenization did not occur regionally, and most ores largely preserve their primary oxygen isotope signatures. Iron isotope analysis showed that ore δ 56 Fe values ranged from –0.44‰ to +1.17‰, with predominantly positive values and the highest values in Type III ore. The δ 56 Fe values covaried with Fe 3+ /(Fe 2+ + Fe 3+ ) ratios among different ore types, reflecting fluctuations in redox conditions during deposition and the geochemical response to oceanic oxidation events, providing robust geochemical evidence for the local manifestation of the Great Oxidation Event (GOE) within the depositional basin. Phase equilibrium modeling indicated that the Changyi BIF experienced peak amphibolite-facies metamorphism at ∼785 °C/6.2 kbar, recording an incomplete prograde P – T path indicative of rapid burial and crustal thickening. Collectively, our results support a genetic model in which the Changyi BIF was deposited in a Paleoproterozoic back-arc basin along an active continental margin, demonstrating that such settings can provide transiently stable depositional environments for Superior-type BIF formation. The deposit systematically documents geochemical responses to both global (GOE) and regional (orogenic metamorphism) events, providing new constraints on the genesis and paleoenvironmental evolution of BIFs in the eastern North China Craton.
Chen et al. (Thu,) studied this question.