EXPERIMENTAL STUDY OF INTERCONNECTIVITY AND GRAIN BOUNDARY WETNESS OF HYDROUS CARBONATITIC LIQUIDS IN MANTLE PERIDOTITE
Tesi di Dottorato
Data di Pubblicazione:
2018
Citazione:
EXPERIMENTAL STUDY OF INTERCONNECTIVITY AND GRAIN BOUNDARY WETNESS OF HYDROUS CARBONATITIC LIQUIDS IN MANTLE PERIDOTITE / L.s. Capizzi ; tutor: S. Poli, P. Fumagalli, S. Tumiati ; coordinator: E. Erba. DIPARTIMENTO DI SCIENZE DELLA TERRA "ARDITO DESIO", 2018 Feb 08. 30. ciclo, Anno Accademico 2017. [10.13130/capizzi-luca-samuele_phd2018-02-08].
Abstract:
Carbon-bearing solids, fluids, and melts in the Earth's deep interior play an important role in the
long-term carbon cycle. Carbonatite magmas have been suggested as important agents of mantle
metasomatism and yet, their physical features are expected to control the mobility from the
source region to shallow Earth. Carbonatites are known to form at relatively low temperatures
and are very mobile, as controlled by their low viscosities and their ability to form an
interconnected grain-edge melt at low melt fraction. The factors promoting migration and
infiltration are the minimization of interfacial energy, the density and chemical gradients, the
thermal diffusion. However, the mobility and infiltration rates of carbonatitic melts, together
with their influence on the annealing of mantle peridotites are poorly constrained processes.
Although natural carbonatitic melts are complex chemical systems with C-O-H species as a
major component, previous work has been performed in anhydrous model systems.
Here we present a quantitative laboratory simulation of variables and processes controlling the
ascent, mobility and connectivity of carbonatites in a model mantle material investigating the
dihedral angle of hydrous carbonatitic liquids. We aim at comparing the texturally equilibrated
volume proportions of volatile-rich carbonatitic melts with silicate melts in a partially molten
peridotite, and and we examine whether carbonatitic liquids are always more wetting than
silicate melts.
The percolation of carbonatitic liquids and the interconnectivity of melt pockets are investigated
by placing a cylindrical dunite rod against a liquid reservoir. As peridotitic matrix we used a
synthetic dunite starting from natural San Carlos olivine powder. Sintering has been performed
in a single stage piston-cylinder apparatus at 0.8 GPa and 1200°C P-T conditions. The liquid
reservoir has a dolomitic composition (Ca0.541, Mg0.389, Fe0.069) CO3 and uses free water as
hydrous source (5 wt.% and 30% of the starting material). Time resolved infiltration experiments
were performed employing an end loaded piston-cylinder apparatus, at T= 1200°C and P = 2.5
GPa. In order to account for the different roles of gravity, chemical diffusion and Ludwig-Soret
diffusion we used two opposite capsule geometries.
Hydrous carbonatitic melt pockets were found along olivine grain boundaries; image analysis on
electron back scattered and X-ray maps allow us quantifying the apparent dihedral angles
between the liquid and olivine and to calculate the grain boundary wetness. Experiments performed at 5 wt. % of water content and 3, 30 and 300 hours of run durations
result in dihedral angles evolving from ∼ 31° for 3 hours run, to ∼ 41° for 300 hours run through
∼ 34° for 30 hours run. The volume of liquid fraction infiltrated provides values of 10 vol.%, 8
vol.% and 2 vol.% for short, medium and long run duration experiments respectively.
Experiments carried out at 30 wt. % of water content and 48 hours of durations show a dihedral
angle values of almost 50° with a range of volume infiltrated melts between 4 to 9 vol. %. The
experimental results indicate that dihedral angles progressively increase with increasing water
dissolved from 25°-28° in anhydrous carbonatitic liquids up to 50° in water-rich carbonatitic
liquids, and, as expected, the volume of interstitial liquid decreases with water increasing.
The increase of wetting angles is representative of a sintering process of the solid matrix, which
evolves with time in the development of channels of pores, as highlighted relating the grain
boundary wetness with fraction of liquid infiltrated. We suggest that the low grain boundary
wetness measured may be due to a relatively
Tipologia IRIS:
Tesi di dottorato
Keywords:
experimental petrology; mantle peridotite; hydrous carbonatitic melts
Elenco autori:
L.S. Capizzi
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