Utilization of multiple geochronology techniques to constrain the age of laterization and mineralization of the world-class Mount Weld rare earth element deposit, Western Australia

Philip L. Verplanck; Cameron Mark Mercer; Jay M. Thompson; Martin Danišík; Heather A. Lowers; Leah E. Morgan; Ganesh Bhat

doi:10.1016/j.chemgeo.2026.123326

Utilization of multiple geochronology techniques to constrain the age of laterization and mineralization of the world-class Mount Weld rare earth element deposit, Western Australia

Chemical Geology

By: Philip L. Verplanck, Cameron Mark Mercer, Jay M. Thompson, Martin Danišík, Heather A. Lowers, Leah E. Morgan, and Ganesh Bhat

https://doi.org/10.1016/j.chemgeo.2026.123326

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Abstract

Pervasive chemical weathering on stable cratons may form thick regoliths and elemental enrichment, but constraining the age of regolith formation is challenging. In this study we utilize multiple geochronological techniques on different minerals from the world-class Mount Weld rare earth element (REE) deposit, formed by lateritic weathering of a carbonatite, to constrain the age of formation and provide insight into landscape evolution. The oldest dates, ca. 100 to 38 Ma, are from Lu-Hf dating of churchite [HREE(PO₄)·2(H₂O)], a heavy REE phosphate mineral. Growth bands on individual minerals show a younging outwards. ⁴⁰Ar/³⁹Ar geochronology of cryptomelane [K(Mn⁴⁺,Mn²⁺)₈O₁₆] yielded dates from ca. 40 to 27 Ma. Similarly, (U-Th)/He geochronology of goethite [FeO(OH)] yielded dates ranging from ca. 45 to 19 Ma.

Integrating results into regional constraints, suggests 1) churchite formed by mineral saturation in a karst-like setting below the water table from ca. 100 to 40 Ma, 2) with minor uplift and erosion, cryptomelane and goethite formed at or near the water table between ca. 45 and 19 Ma, 3) after ca. 15 to 10 Ma chemical weathering within the profile had ended. Other studies document that the region experienced minimal uplift and a wet, warm climate from ca. 100 Ma to 15 Ma. These conditions and the high carbonate content of the carbonatite promote extensive chemical weathering, a deep weathering profile, and the preservation of the weathered section. This study highlights the use of multiple geochronological techniques utilizing different minerals to provide insight into how laterites form and to constrain the timing and history of the formation of this important mineral deposit.

Suggested Citation

Verplanck, P.L., Mercer, C.M., Thompson, J.M., Danišík, M., Lowers, H.A., Morgan, L.E., and Bhat, G., 2026, Utilization of multiple geochronology techniques to constrain the age of laterization and mineralization of the world-class Mount Weld rare earth element deposit, Western Australia: Chemical Geology, v. 709, 123326, 19 p., https://doi.org/10.1016/j.chemgeo.2026.123326.

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Additional publication details
Publication type	Article
Publication Subtype	Journal Article
Title	Utilization of multiple geochronology techniques to constrain the age of laterization and mineralization of the world-class Mount Weld rare earth element deposit, Western Australia
Series title	Chemical Geology
DOI	10.1016/j.chemgeo.2026.123326
Volume	709
Year Published	2026
Language	English
Publisher	Elsevier
Contributing office(s)	Geology, Geophysics, and Geochemistry Science Center
Description	123326, 19 p.
Country	Australia
Other Geospatial	Western Australia