Control and monitoring of oxygen fugacity in piston cylinder experiments

We present a newly developed capsule design that resolves some common problems associated with the monitoring and control of oxygen fugacity ( f O 2 ) in high-pressure piston cylinder experiments. The new f O 2 control assembly consists of an AuPd outer capsule enclosing two inner capsules: one of A...

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Veröffentlicht in:	Contributions to mineralogy and petrology 2015-01, Vol.169 (1), p.1, Article 9
Hauptverfasser:	Matjuschkin, Vladimir, Brooker, Richard A., Tattitch, Brian, Blundy, Jon D., Stamper, Charlotte C.
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Schlagworte:	Aluminum oxide Earth and Environmental Science Earth Sciences Experiments Geology Hydrogen Mineral Resources Mineralogy Original Paper Oxygen Patient monitoring equipment Permeability Petrology Sensors
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description	We present a newly developed capsule design that resolves some common problems associated with the monitoring and control of oxygen fugacity ( f O 2 ) in high-pressure piston cylinder experiments. The new f O 2 control assembly consists of an AuPd outer capsule enclosing two inner capsules: one of AuPd capsule containing the experimental charge (including some water), and the other of Pt containing a solid oxygen buffer plus water. The inner capsules are separated by crushable alumina. The outer capsule is surrounded by a Pyrex sleeve to simultaneously minimise hydrogen loss from the cell and carbon infiltration from the graphite furnace. Controlled f O 2 experiments using this cell design were carried out at 1.0 GPa and 1,000 °C. We used NiPd, CoPd and (Ni, Mg)O f O 2 sensors, whose pressure sensitivity is well calibrated, to monitor the redox states achieved in experiments buffered by Re–ReO 2 , Ni–NiO and Co–CoO, respectively. Results for the f O 2 sensors are in good agreement with the intended f O 2 established by the buffer, demonstrating excellent control for durations of 24–48 h, with uncertainties less than ± 0.3 log bar units of f O 2 .
doi_str_mv	10.1007/s00410-015-1105-z
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subjects	Aluminum oxide Earth and Environmental Science Earth Sciences Experiments Geology Hydrogen Mineral Resources Mineralogy Original Paper Oxygen Patient monitoring equipment Permeability Petrology Sensors
title	Control and monitoring of oxygen fugacity in piston cylinder experiments
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