The role of phosphorus in crystallisation processes of basalt: An experimental study
To evaluate the effects of phosphorus on differentiation of evolved basaltic magmas, a series of one-atmosphere experiments on a ferrobasaltic composition were carried out over a range of P 2O 5 contents and at oxygen fugacities from 2 log 10 units below to 2 log 10 units above the fayalite-magnetit...
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Published in | Geochimica et cosmochimica acta Vol. 58; no. 2; pp. 797 - 810 |
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Main Authors | , , |
Format | Journal Article |
Language | English |
Published |
Elsevier Ltd
1994
|
Online Access | Get full text |
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Summary: | To evaluate the effects of phosphorus on differentiation of evolved basaltic magmas, a series of one-atmosphere experiments on a ferrobasaltic composition were carried out over a range of P
2O
5 contents and at oxygen fugacities from 2 log
10 units below to 2 log
10 units above the fayalite-magnetite-quartz (FMQ) buffer curve. The experiments were performed isothermally, the investigated variables being the amount of added P
2O
5 and the oxygen fugacity (f
o
2
). The results confirm the high solubility of phosphorus in basaltic magmas and show that, at fixed temperature, the progressive addition of phosphorus causes:
1.
(1) the disappearance of olivine at reducing conditions,
2.
(2) the disappearance of magnetite at oxidising conditions,
3.
(3) the stabilisation of pigeonite throughout the studied range of f
o
2
,
4.
(4) an increase in the modal plagioclase/pyroxene ratio, and
5.
(5) increased melt proportion and large changes in the composition of the coexisting melt, in particular the SiO
2 content.
The destabilisation of magnetite with increasing P
2O
5 content may be accounted for by the formation of Fe
3+(PO
4)
3− complexes, rather than by a large change of the redox ratio of the melt; we suggest that the formation of Fe
3+(PO
4)
3− complexes dominates that of P-O-
M complexes (where
M is a network-modifying cation). The effect of P on the modal proportions of plagioclase and pigeonite may help to explain the mineralogy of some anorthositic rocks and KREEP basalts, as well as the presence of pigeonite as an intercumulus phase in the Skaergaard intrusion (resulting from enrichment of the trapped liquid in phosphorus). These new results thus provide insights into the effects of phosphorus in lunar and terrestrial systems, as well as providing information regarding the structural role of phosphorus in silicate melts. |
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ISSN: | 0016-7037 1872-9533 |
DOI: | 10.1016/0016-7037(94)90506-1 |