Experimental calibration of Forsterite–Anorthite–Ca-Tschermak–Enstatite (FACE) geobarometer for mantle peridotites

The crystallization of plagioclase-bearing assemblages in mantle rocks is witness of mantle exhumation at shallow depth. Previous experimental works on peridotites have found systematic compositional variations in coexisting minerals at decreasing pressure within the plagioclase stability field. In...

Full description

Saved in:
Bibliographic Details
Published in:Contributions to mineralogy and petrology 2017-06, Vol.172 (6), p.1, Article 38
Main Authors: Fumagalli, P., Borghini, G., Rampone, E., Poli, S.
Format: Article
Language:English
Subjects:
Anorthite
Crystallization
Cylinders
Earth and Environmental Science
Earth Sciences
Enstatite
Forsterite
Gels
Geochemistry
Geology
Lithosphere
Magma
Mantle
Mineral Resources
Mineralogy
Minerals
Monte Carlo simulation
Original Paper
Peridotite
Petrology
Plagioclase
Rocks
Spinel
Stability
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:The crystallization of plagioclase-bearing assemblages in mantle rocks is witness of mantle exhumation at shallow depth. Previous experimental works on peridotites have found systematic compositional variations in coexisting minerals at decreasing pressure within the plagioclase stability field. In this experimental study we present new constraints on the stability of plagioclase as a function of different Na 2 O/CaO bulk ratios, and we present a new geobarometer for mantle rocks. Experiments have been performed in a single-stage piston cylinder at 5–10 kbar, 1050–1150 °C at nominally anhydrous conditions using seeded gels of peridotite compositions (Na 2 O/CaO = 0.08–0.13; X Cr = Cr/(Cr + Al) = 0.07–0.10) as starting materials. As expected, the increase of the bulk Na 2 O/CaO ratio extends the plagioclase stability to higher pressure; in the studied high-Na fertile lherzolite (HNa-FLZ), the plagioclase-spinel transition occurs at 1100 °C between 9 and 10 kbar; in a fertile lherzolite (FLZ) with Na 2 O/CaO = 0.08, it occurs between 8 and 9 kbar at 1100 °C. This study provides, together with previous experimental results, a consistent database, covering a wide range of P – T conditions (3–9 kbar, 1000–1150 °C) and variable bulk compositions to be used to define and calibrate a geobarometer for plagioclase-bearing mantle rocks. The pressure sensitive equilibrium: M g 2 Si O 4 Ol Forsterite + CaA l 2 S i 2 O 8 Pl Anorthite = CaA l 2 Si O 6 Cpx Ca-Tschermak + M g 2 S i 2 O 6 Opx Enstatite , has been empirically calibrated by least squares regression analysis of experimental data combined with Monte Carlo simulation. The result of the fit gives the following equation: P = 7.2 ( ± 2.9 ) + 0.0078 ( ± 0.0021 ) T + 0.0022 ( ± 0.0001 ) T ln K , R 2 = 0.93 , where P is expressed in kbar and T in kelvin. K is the equilibrium constant K  =  a CaTs × a en / a an × a fo , where a CaTs , a en , a an and a fo are the activities of Ca-Tschermak in clinopyroxene, enstatite in orthopyroxene, anorthite in plagioclase and forsterite in olivine. The proposed geobarometer for plagioclase peridotites, coupled to detailed microstructural and mineral chemistry investigations, represents a valuable tool to track the exhumation of the lithospheric mantle at extensional environments.
ISSN:0010-7999
1432-0967
DOI:10.1007/s00410-017-1352-2