Fluid-Assisted Aggregation and Assembly of Magnetite Microparticles in the Giant El Laco Iron Oxide Deposit, Central Andes
School authors:
author photo
Gloria Cecilia Arancibia
External authors:
  • J. Tomais Ovalle ( Universidad de Chile , University of Michigan )
  • Martin Reich ( Universidad de Chile )
  • Fernando Barra ( Universidad de Chile )
  • Adam C. Simon ( University of Michigan )
  • Belinda Godel ( Commonwealth Scientific & Industrial Research Organisation (CSIRO) )
  • Margaux Le Vaillant ( Commonwealth Scientific & Industrial Research Organisation (CSIRO) )
  • Gisella Palma ( Universidad Mayor )
  • Artur P. Deditius ( Murdoch University , University of Western Australia )
  • Gert Heuser ( Pontificia Universidad Catolica de Chile , Universidad de Chile )
  • Diego Morata ( Universidad de Chile )
Abstract:

The El Laco iron oxide mineral deposit in the CentralAndes ofChile has attracted significant attention because of its uniquelypreserved massive magnetite orebodies, which bear a remarkable similarityto volcanic products. To date, the outcropping highly vesicular andporous massive magnetite orebodies have received little attentionfrom a microtextural point of view, limiting our understanding aboutthe role of volcanogenic processes on iron mineralization. Here, wereport the chemical composition of vesicular magnetite at El Lacousing EPMA and LA-ICP-MS methods and provide detailed 2D and 3D imagingof the internal structure of these texturally complex magnetite oresby combining SEM observations, synchrotron radiation micro-X-ray fluorescencechemical mapping, and high-resolution X-ray computed microtomography.Our observations reveal the presence of abundant magnetite microsphereswith diameters ranging from & SIM;100 to & SIM;900 & mu;m, aswell as dendritic microstructures forming interconnected networksup to a few millimeters in size. Two-dimensional microtextural andgeochemical imaging of the microspheres show that these features areformed by multiple euhedral magnetite crystals growing in all directionsand occur immersed within a porous matrix conformed by smaller-sized(& SIM;2-20 & mu;m) and irregularly shaped magnetite microparticles.These types of morphologies have been reported in hydrothermal ventsassociated with hydrovolcanic processes and commonly described inhydrothermal synthesis experiments of magnetite microspheres, suggestingprecipitation from iron-rich fluids. A hydrothermal origin for themagnetite microparticles reported here is further supported by theirgeochemical signature, which shows a strong depletion in most minorand trace elements typical from magnetite precipitated from hydrothermalfluids in ore-forming environments. We propose that decompression,cooling, and boiling of fluids triggered massive iron supersaturation,resulting in the nucleation of magnetite microparticles or colloids,followed by self-assembly into larger and more complex microstructures.Our data from El Laco deposit agree with models invoking magmatic-hydrothermalfluids to explain the origin of the deposit and provide new insightson the potential role of iron colloids as agents of mineralizationin volcanic systems.

UT WOS:001018209700001
Number of Citations 4
Type
Pages 1378-1387
ISSUE 7
Volume 7
Month of Publication MAY 15
Year of Publication 2023
DOI https://doi.org/10.1021/acsearthspacechem.3c00036
ISSN
ISBN