Phase Relations in the System MgSiO3‐Al2O3 up to 2300 K at Lower Mantle Pressures

Phase relations in the system MgSiO3‐Al2O3 were investigated at pressures of 27–45 GPa and temperatures of 1700, 2000, and 2300 K using sintered diamond and tungsten carbide anvils in a multianvil apparatus. The bulk compositions in the MgSiO3‐Al2O3 binary system crystallize a phase assemblage of py...

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Bibliographic Details
Published in:Journal of geophysical research. Solid earth 2017-10, Vol.122 (10), p.7775-7788
Main Authors: Liu, Zhaodong, Nishi, Masayuki, Ishii, Takayuki, Fei, Hongzhan, Miyajima, Nobuyoshi, Ballaran, Tiziana Boffa, Ohfuji, Hiroaki, Sakai, Takeshi, Wang, Lin, Shcheka, Svyatoslav, Arimoto, Takeshi, Tange, Yoshinori, Higo, Yuji, Irifune, Tetsuo, Katsura, Tomoo
Format: Article
Language:eng ; jpn
Subjects:
Al2O3
bridgmanite
lower mantle
phase relations
subducted slabs
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Summary:Phase relations in the system MgSiO3‐Al2O3 were investigated at pressures of 27–45 GPa and temperatures of 1700, 2000, and 2300 K using sintered diamond and tungsten carbide anvils in a multianvil apparatus. The bulk compositions in the MgSiO3‐Al2O3 binary system crystallize a phase assemblage of pyrope and corundum at pressures below 27 GPa and an assemblage of bridgmanite and corundum at pressures above 27 GPa regardless of temperatures. The solubility of Al2O3 in bridgmanite and that of MgSiO3 in corundum increases significantly with increasing temperature. The solubility of Al2O3 in bridgmanite increases from 6.7 mol % at 1700 K to 21.8 mol % at 2500 K under a constant pressure of 27 GPa. Bridgmanite becomes more aluminous with increasing pressure from 27 to 45 GPa at a given temperature. The MgSiO3 content in corundum increases with increasing pressure at pressure lower than 27 GPa, while it decreases at pressure higher than 27 GPa. Our results suggest that bridgmanite can incorporate a considerably higher Al2O3 content than that of the pyrope composition (25 mol % Al2O3). The present study further suggests that the entire Al2O3 component is accommodated into bridgmanite in the pyrolite lower mantle. However, Al2O3 cannot be fully accommodated into bridgmanite in the coldest parts of subducted slabs in the shallow part of the lower mantle, and therefore, additional phases such as MgAl2O4 with calcium ferrite‐type structure are necessary to host the excess Al2O3. Plain Language Summary Here we determined the phase relations in the system MgSiO3‐Al2O3 up to 2300 K under lower mantle pressures and found that the solubility of Al2O3 in bridgmanite and that of MgSiO3 in corundum increase with increasing temperature. All Al2O3 can be completely accommodated into bridgmanite in the pyrolite composition, while the Al2O3 cannot be fully accommodated into bridgmanite in the coldest parts of subducted slabs, and therefore, additional phases are required to host the excess Al2O3. Key Points Phase relations in the system MgSiO3‐Al2O3 were determined at temperatures up to 2300 K and pressures up to 45 GPa The solubility of Al2O3 in bridgmanite and that of MgSiO3 in corundum increases with increasing temperature The Al2O3 cannot be fully accommodated in the coldest parts of subducted slabs in the shallow part of the lower mantle
ISSN:2169-9313
2169-9356
DOI:10.1002/2017JB014579