Oxidation processes and thermal stability of actinolite

Understanding the thermal behaviour of iron-containing amphiboles (AB 2 C 5 T 8 O 22 W 2 , C 5  =  M (1) 2  M (2) 2  M (3)) at atomic-level scale may have important implications in several fields, including metamorphic petrology, geophysics, and environmental sciences. Here, the thermally induced ox...

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Published in:Physics and chemistry of minerals 2022-12, Vol.49 (12), Article 47
Main Authors: Rösche, Constanze, Waeselmann, Naemi, Petrova, Nadia, Malcherek, Thomas, Schlüter, Jochen, Mihailova, Boriana
Format: Article
Language:English
Subjects:
Amphiboles
Calcium magnesium silicates
Cations
Chains
Conduction electrons
Crystal defects
Crystallography and Scattering Methods
Current carriers
Decomposition
Dehydrogenation
Diopside
Disintegration
Earth and Environmental Science
Earth Sciences
Environmental science
Geochemistry
Geophysics
High temperature
Hydroxyl groups
Iron
Mineral Resources
Mineralogy
Original Paper
Oxidation
Petrology
Pyroxenes
Raman spectroscopy
Spectrometry
Thermal stability
Thermodynamic properties
Tremolite
X-ray diffraction
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Summary:Understanding the thermal behaviour of iron-containing amphiboles (AB 2 C 5 T 8 O 22 W 2 , C 5  =  M (1) 2  M (2) 2  M (3)) at atomic-level scale may have important implications in several fields, including metamorphic petrology, geophysics, and environmental sciences. Here, the thermally induced oxidation and decomposition of actinolite are studied by in situ high-temperature Raman spectroscopy and complementary thermogravimetric/mass-spectrometry analyses as well as X-ray diffraction of the products of amphibole decomposition. The effect of C Fe 2+ on dehydrogenation/dehydroxylation is followed by comparing the results on actinolite with those for tremolite. We show that mobile charge carriers, namely polarons (conduction electrons coupled to FeO 6 phonons) and H + cations, exist in actinolite at elevated temperatures ~ 1150–1250 K. The temperature-induced actinolite breakdown is a multistep process, involving (i) delocalization of e − from C Fe 2+ as well as of H + from hydroxyl groups shared by Fe-containing M (1) M (1) M (3) species, which, however, remain in the crystal bulk; (ii) dehydrogenation and ejection of e − between 1250 and 1350 K, where actinolite can be considered as “oxo-actinolite”, as H + also from hydroxyl groups next to M (1,3) (MgMgMg) configurations become delocalized and mostly remain in the crystal bulk; (iii) complete dehydroxylation and consequent structure collapse above 1350 K, forming an Fe 3+ -bearing defect-rich augitic pyroxene. The dehydrogenation of tremolite occurs at 1400 K, triggering immediately a disintegration of the silicate double-chain into single SiO 4 -chains and followed by a rearrangement of the amphibole octahedral strips and B Ca 2+ cations into pyroxene-type octahedral sheets at 1450 K. The result of tremolite decomposition is also a single-phase defect-rich clinopyroxene with an intermediate composition on the diopside–clinoenstatite join.
ISSN:0342-1791
1432-2021
DOI:10.1007/s00269-022-01223-4