Journal
CHEMICAL GEOLOGY
Volume 270, Issue 1-4, Pages 240-248Publisher
ELSEVIER
DOI: 10.1016/j.chemgeo.2009.12.003
Keywords
Ammonium; Clinopyroxene; Nitrogen cycle; High pressure; IR spectroscopy; Earth's mantle
Categories
Funding
- German Science Foundation [He 2015/(8-1)]
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In the pseudobinary system CaMgSi2O6-(NH4)M3+Si2O6, with M = Cr or Al, and NH4OH in excess, multi-anvil experiments at 9.5 to 12.8 GPa, 725 to 750 degrees C produced NH4-bearing diopside. Incorporation mainly follows the coupled substitution (Ca-)M2(2+) + (Mg2+)(M1) double left right arrow (NH4+)(M2) + (M3+)(M1). Ammonium was identified and quantified by IR spectroscopy. In Cr-bearing diopside we found maximum concentrations in the range of 500 to 1000 ppm, of NH4. The storage capacity of mantle clinopyroxenes for ammonium turns them to potential candidates for the nitrogen reservoir in the Earth's upper mantle, and this mechanism also contributes to its water budget. While nitrogen is transported into the mantle via cold slabs through NH4 inherited from sedimentary material, and stored in K-bearing minerals and successor high-pressure phases, nitrogen output from the mantle is through degassing of N-2. A probable mechanism for that is that nitrogen is kept as NH4 in clinopyroxene in the Earth's mid- and lower mantle, whereas in the upper part, it is lost due to oxidation to molecular nitrogen. It is most likely that clinopyroxene plays a major role in the long-time, large-scale nitrogen cycle between surface and deep mantle of the Earth. (C) 2009 Elsevier B.V. All rights reserved.
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