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Modeling magma to find copper

Date:
January 12, 2017
Source:
Université de Genève
Summary:
Copper is an essential element of our society with main uses in the field of electricity and electronics. About 70% of the copper comes from deposits formed several million years ago during events of magma degassing within Earth's crust just above subduction zones. Despite similar ore forming processes, the size of these deposits can vary orders of magnitude from one place to another, the main reason of which has remained unclear. A new study suggests that the answer may come from the volume of magma emplaced in the crust and proposes an innovative method to better explore these deposits.
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Copper is an essential element of our society with main uses in the field of electricity and electronics. About 70% of the copper comes from deposits formed several million years ago during events of magma degassing within Earth's crust just above subduction zones. Despite similar ore forming processes, the size of these deposits can vary orders of magnitude from one place to another, the main reason of which has remained unclear. A new study led by researchers from the Universities of Geneva (UNIGE, Switzerland) and the Saint-Etienne (France), to be published in Scientific Reports, suggests that the answer may come from the volume of magma emplaced in the crust and proposes an innovative method to better explore these deposits.

Magmas formed above subduction zones contain important amount of water that is essentially degassed during volcanic eruptions or upon magma cooling and solidification at depth. The water escaping from the crystallizing magma at several kilometers below surface carries most of the copper initially dissolved in the magma. On its way toward the surface the magmatic fluids cool and deposit copper in the fractured rocks forming giant metal deposits such as those exploited along the Andean Cordillera.

By modeling the process of magma degassing, the researchers could reproduce the chemistry of the fluids that form metal deposits. "Comparing the model results with available data from known copper deposits, we could link the timescales of magma emplacement and degassing in the crust, the volume of magma, and the size of the deposit," explains Luca Caricchi, researcher at the UNIGE. The scientists also propose a new method to estimate the size of the deposits, based on high-precision geochronology, one of the specialties of the Department of Earth Sciences in UNIGE's Science Faculty.

This technique is a new add-in in the prospector toolbox with the possibility to identify deposits with the best potential, early in the long and costly process of mineral exploration. It is anticipated that the computational approach developed in this study can also provide important insights on the role of magma degassing as a potential trigger for volcanic eruptions.


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Materials provided by Université de Genève. Note: Content may be edited for style and length.


Journal Reference:

  1. Cyril Chelle-Michou, Bertrand Rottier, Luca Caricchi, Guy Simpson. Tempo of magma degassing and the genesis of porphyry copper deposits. Scientific Reports, 2017; 7: 40566 DOI: 10.1038/srep40566

Cite This Page:

Université de Genève. "Modeling magma to find copper." ScienceDaily. ScienceDaily, 12 January 2017. <www.sciencedaily.com/releases/2017/01/170112083722.htm>.
Université de Genève. (2017, January 12). Modeling magma to find copper. ScienceDaily. Retrieved December 22, 2024 from www.sciencedaily.com/releases/2017/01/170112083722.htm
Université de Genève. "Modeling magma to find copper." ScienceDaily. www.sciencedaily.com/releases/2017/01/170112083722.htm (accessed December 22, 2024).

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