Abstract
Abstract The presence of sulfate-rich fluids in natural magmatic hydrothermal systems and some carbonatite-related rare earth element (REE) deposits is paradoxical, because sulfate salts are known for their retrograde solubility, implying that they should be insoluble in high-temperature geofluids. Here, we show that the presence of quartz can significantly change the dissolution behavior of Na2SO4, leading to the formation of extremely sulfate-rich fluids (at least 42.8 wt% Na2SO4) at temperatures >∼330 °C. The elevated Na2SO4 solubility results from prograde dissolution of immiscible sulfate melt, the water-saturated solidus of which decreases from ≥∼450 °C in the binary Na2SO4-H2O system to ∼270 °C in the presence of silica. This implies that sulfate-rich fluids should be common in quartz-saturated crustal environments. Furthermore, we found that the sulfate-rich fluid is a highly effective medium for Nd mobilization. Thermodynamic modeling predicts that sulfate ions are more effective in complexing REE(III) than chloride ions. This reinforces the idea that REEs can be transported as sulfate complexes in sulfate-rich fluids, providing an alternative to the current REE transport paradigm, wherein chloride complexing accounts for REE solubility in ore fluids.
Highlights
Sulfate is ubiquitous in Earth and terrestrial planets or moons such as Mars and Europa (McCord et al, 1998; Chipera and Vaniman, 2007; Debret and Sverjensky, 2017)
Previous studies have shown that silica-saturated sulfate solutions contain significant amounts of sulfate-silica complexes (Marshall and Chen, 1982; Schmidt, 2009; Wang et al, 2016) and show complex phase transitions upon heating (Kotel’nikova and Kotel’nikov, 2010), suggesting that quartz, a ubiquitous mineral in the crust, may influence the solubility and phase relationships in sulfate-water systems
We show that the presence of quartz switches the solubility of Na2SO4 and Nd2(SO4)3 from retrograde to prograde at temperatures typical of hydrothermal rare earth element (REE) mineralization, significantly changing the behavior of the sulfate-water systems
Summary
Sulfate is ubiquitous in Earth and terrestrial planets or moons such as Mars and Europa (McCord et al, 1998; Chipera and Vaniman, 2007; Debret and Sverjensky, 2017). We show that the presence of quartz switches the solubility of Na2SO4 and Nd2(SO4)3 from retrograde to prograde at temperatures typical of hydrothermal REE mineralization, significantly changing the behavior of the sulfate-water systems. RESULTS AND DISCUSSION To explore the high-temperature behavior of quartz-saturated sulfate-water systems and to evaluate their ability to transport REEs, we conducted hydrothermal diamond anvil cell (HDAC; Bassett et al, 1996) experiments on the Na2SO4-SiO2-H2O and Na2SO4-Nd2(SO4)3SiO2-H2O systems.
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