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Please use this identifier to cite or link to this item:
http://hdl.handle.net/10174/34346
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Title: | Mineralogical and chemical changes induced by experiments of interaction between supercritical CO2 and plutonic mafic rocks. A case study in Portugal. |
Authors: | Moita, P, Berrezueta, E. Abdoulghafour, H. Beltrame, M. Mirão, J. Ribeiro, C. Barrulas, P. Pedro, J. Carneiro, J. |
Keywords: | in-situ carbonation gabbros Sines InCarbon |
Issue Date: | 23-May-2022 |
Publisher: | EGU General Assembly 2022 |
Citation: | Moita, P., Berrezueta, E., Abdoulghafour, H., Beltrame, M., Mirão, J., Ribeiro, C., Barrulas, P., Pedro, J., and Carneiro, J.: Mineralogical and chemical changes induced by experiments of interaction between supercritical CO2 and plutonic mafic rocks. A case study in Portugal., EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-5158, https://doi.org/10.5194/egusphere-egu22-5158, 2022. |
Abstract: | The focus of this research is a qualitative study of mineralogical and chemical changes in plutonic
mafic rock samples after exposure to a CO2-rich brine, under supercritical conditions (SC), to clarify
the behavior of brine and rock in the initial stages of mineral carbonation. The studied rock
consists of a gabbro-anorthosite from the Odivelas massif, in southern Portugal. The sample was
exposed to a SC CO2-rich brine (P≈8 MPa, T≈40◦C) for runs of 0, 30 and 90 days. Experiments were
conducted in batch mode, ie. with no CO2 flow, and with a proportion of CO2 to brine of 0.226 for
30 days and 0.033 for 90 days. In addition, numerical modeling was applied to complement the
experimental observations, reproducing the experimental observations and simulate the chemical
behavior for longer times. The chemical analysis of the brine, before and after, the experiment,
shows: (i) increase of magnesium (Mg2+), calcium (Ca2+) and silica (SiO2) for the 30 and 90 days runs
and (ii) decrease of pH (8.1 to 6.1 and 8.1 to 6.3, respectively). Experimental and numerical results
indicate that the rock sample suffered a slight dissolution process with mineralogical/textural
readjustments on the external area of the specimens studied. This is thought to mimic the initial
dissolution process under early-stage mineral carbonation. After 90 days, apart from halite, there
are no significant new mineral phases. However, the elemental association in the EDS maps of
carbon and magnesium dissociated from silicon suggests the residual crystallization of magnesite |
URI: | http://hdl.handle.net/10174/34346 |
Type: | lecture |
Appears in Collections: | HERCULES - Comunicações - Em Congressos Científicos Internacionais
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