Abstract
Serpentinite powdered samples from four different regions were characterized using scanning electron microscopy (SEM), X-ray diffraction (XRD), SBET and porosity measurements, UV-Vis and Infrared Spectroscopy of the skeletal region and surface OH groups. SEM micrographs of the samples showed a prismatic morphology when the lizardite was the predominant phase, while if antigorite phase prevailed, the particles had a globular morphology. The few fibrous-shaped particles, only observed by SEM and weakly detected by XRD on MO-9C and MO13 samples, were characteristic of the chrysotile phase. All diffraction XRD patterns showed characteristic peaks of antigorite and lizardite serpentine phases, with crystallite sizes in the range 310–250 Å and with different degrees and types of carbonation processes, one derived from the transformation of the serpentine, generating dolomite, and another by direct precipitation of calcite. The SBET reached values between 38–24 m2∙g−1 for the samples less crystalline, in agreement with the XRD patterns, while those with a higher degree of crystallinity gave values close to 8–9 m2∙g−1. In the UV region all electronic spectra were dominated by the absorption edge due to O2− → Si4+ charge transfer transition, with Si4+ in tetrahedral coordination, corresponding to a band gap energy of ca 4.7 eV. In the visible region, 800–350 nm, the spectra of all samples, except Donai, presented at least two weak and broad absorptions centred in the range 650–800 and 550–360 nm, associated with the presence of Fe3+ ions from the oxidation of structural Fe2+ ions in the serpentinites ((MgxFe2+1−x)3Si2O5(OH)4). The relative intensity of the IR bands corresponding to the stretching modes of the OH’s groups indicated the prevalence of one of the two phases, antigorite or lizardite, in the serpentinites. We proposed that the different relative intensity of these bands could be considered as diagnostic to differentiate the predominance of these phases in serpentinites.
Highlights
Serpentine minerals are phyllosilicates with a large metamorphic stability field that is generally formed during the hydration of basic to ultrabasic rocks
We reported the results of a characterization study by Scanning Electron Micrographs (SEM) microscopy, X-ray diffraction (XRD) and IR
Scanning electron microscopy (SEM) studies were recorded with a Zeiss EM 900 instrument
Summary
Serpentine minerals are phyllosilicates with a large metamorphic stability field that is generally formed during the hydration of basic to ultrabasic rocks. Details of their physicochemical properties such as the crystal structure of the most common phase lizardite and antigorite are still a matter of controversy. The behaviour of these rocks seems to be dependent on the serpentine phase that is predominant in their composition [8,9] sometimes it is not easy to identify them by traditional petrographic methods. Our interest in this study was to deepen the understanding of the physicochemical properties of this important family of materials and propose a quick and easy method in order to discern each of the phases that were mixed in these serpentine minerals
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