Low δ¹⁸O rocks in the Belomorian belt, NW Russia, and Scourie dikes, NW Scotland: a record of ancient meteoric water captured by the early Paleoproterozoic global mafic magmatism

The 2.45-2.38 Ga intrusions and their host rocks in the Belomorian belt of NW Russia and the Scourie dikes of the Lewisian complex in NW Scotland are marked by extremely low δ¹⁸O values. Their isotope signatures reflect high-temperature exchange between rocks and low δ¹⁸O meteoric waters representing a record of active hydrologic cycle early in the Earth’s history. Here we explore triple oxygen and hydrogen isotope systematics (δD, δ¹⁸O and Δ¹⁷O) of these rocks to evaluate the isotopic composition of meteoric water. The new occurrences from Belomorian belt range in δ¹⁸O from -14 to -2 ‰; combined with previously reported data, ranging between -27 and +3 ‰, the low δ¹⁸O rocks are traced across 500 km of the Belomorian belt. Based on spatial distribution of the values, hydrothermal alteration driven by the emplacement of the mafic intrusions is the most consistent explanation for the low δ¹⁸O values recorded in the Belomorian belt. The Δ¹⁷O systematics reveals contribution of distinct meteoric waters with δ¹⁸O of −38 and −9 ‰ recorded at different localities across the belt. We also present new data for the 2.41-2.38 Ga Scourie dikes, with the lowest δ¹⁸O value of -2.5 ‰ recorded in the amphiboles of Loch na h dike. Unlike the Belomorian belt, the low δ¹⁸O signature of Scourie dikes requires igneous incorporation of low δ¹⁸O hydrothermally altered rocks through contamination of mantle-derived melts. The Δ¹⁷O data analyzed at the Loch na h dike reveals that the incorporated material experienced water-rock interaction with meteoric water that had δ¹⁸O of −35 ± 10 ‰. The exact mechanism for incorporation of such low δ¹⁸O rocks in the mafic Scourie dike melts is equivocal and could involve subduction or assimilation of low δ¹⁸O hydrothermally altered mafic rocks. These reconstructed isotopic compositions of meteoric waters are diverse and comparable to the modern-day precipitation of high-latitude regions (e.g. Greenland, δ¹⁸O = −35 ‰) and precipitation of mid-latitude regions (−9 ‰), possibly reflecting spatial δ¹⁸O gradients resulted from an active hydrologic cycle during the cold climate of the early Paleoproterozoic, as depicted by previous isotope-enabled global circulation models of snowball Earth state.