A Comprehensive Methodology for Monitoring Evaporitic
Mineral Precipitation and Hydrochemical Evolution of Saline Lakes:
The Case of Lake Magadi Soda Brine (East African Rift Valley, Kenya)
posted on 2022-03-03, 23:13authored byMelese Getenet, Juan Manuel García-Ruiz, Fermín Otálora, Franziska Emmerling, Dominik Al-Sabbagh, Cristóbal Verdugo-Escamilla
Lake
Magadi, East African Rift Valley, is a hyperalkaline and saline
soda lake highly enriched in Na+, K+, CO32–, Cl–, HCO3–, and SiO2 and depleted in Ca2+ and Mg2+, where thick evaporite deposits and siliceous
sediments have been forming for 100 000 years. The hydrogeochemistry and the evaporite deposits
of soda lakes are subjects of growing interest in paleoclimatology,
astrobiology, and planetary sciences. In Lake Magadi, different hydrates
of sodium carbonate/bicarbonate and other saline minerals precipitate.
The precipitation sequence of these minerals is a key for understanding
the hydrochemical evolution, the paleoenvironmental conditions of
ancient evaporite deposits, and industrial crystallization. However,
accurate determination of the precipitation sequence of these minerals
was challenging due to the dependency of the different hydrates on
temperature, water activity, pH and pCO2, which could induce
phase transformation and secondary mineral precipitation during sample
handling. Here, we report a comprehensive methodology applied for
monitoring the evaporitic mineral precipitation and hydrochemical
evolution of Lake Magadi. Evaporation and mineral precipitations were
monitored by using in situ video microscopy and synchrotron X-ray
diffraction of acoustically levitated droplets. The mineral patterns
were characterized by ex situ Raman spectroscopy, X-ray diffraction,
and scanning electron microscopy. Experiments were coupled with thermodynamic
models to understand the evaporation and precipitation-driven hydrochemical
evolution of brines. Our results closely reproduced the mineral assemblages,
patterns, and textural relations observed in the natural setting.
Alkaline earth carbonates and fluorite were predicted to precipitate
first followed by siliceous sediments. Among the salts, dendritic
and acicular trona precipitate first via fractional crystallizationreminiscent
of grasslike trona layers of Lake Magadi. Halite/villiaumite, thermonatrite,
and sylvite precipitate sequentially after trona from residual brines
depleted in HCO3–. The precipitation
of these minerals between trona crystals resembles the precipitation
process observed in the interstitial brines of the trona layers. Thermonatrite
precipitation began after trona equilibrated with the residual brines
due to the absence of excess CO2 input. We have shown that
evaporation and mineral precipitation are the major drivers for the
formation of hyperalkaline, saline, and SiO2-rich brines.
The discrepancy between predicted and actual sulfate and phosphate
ion concentrations implies the biological cycling of these ions. The
combination of different in situ and ex situ methods and modeling
is key to understanding the mineral phases, precipitation sequences,
and textural relations of modern and ancient evaporite deposits. The
synergy of these methods could be applicable in industrial crystallization
and natural brines to reconstruct the hydrogeochemical and hydroclimatic
conditions of soda lakes, evaporite settings, and potentially soda
oceans of early Earth and extraterrestrial planets.