Abstract
RECENT high-pressure experiments1–3 suggest that the Earth's lower mantle is composed of MgSiO3 and CaSiO3 perovskites, (Mg, Fe)O magnesiowiistite, and a minor but significant amount of aluminous phases, such as majorite garnet or an unidentified Al-rich phase. The stability of majorite garnet and the nature of any such aluminous phase, however, are controversial issues rele-vant to the mineralogy of the lower mantle4–7. Here I report an experimental study of the phase transformations that occur in a pyrolite mantle composition with increasing pressure from 23 to 28 GPa (equivalent to ∼650–770 km depth in the mantle). The results demonstrate that majorite garnet completely transforms to perovskite structures at pressures above 26 GPa (>720 km depth). A12O3 is accommodated mainly in MgSiO3 perovskite, and no separate aluminous phase was observed at higher pressures, leading to the conclusion that the upper part of the Earth's lower mantle is composed only of two perovskites and magnesiowüstite.
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References
Ito, E. & Takahashi, E. in High-Pressure Research in Mineral Physics. (eds Manghnani, M. H. & Syono, Y.) 221–230 (Terra Publ./American Geophysical Union, Tokyo, 1987).
Takahashi, E. & Ito, E. in High-Pressure Research in Mineral Physics. (eds Manghnani, M. H. & Syono, Y.) 427–437 (Terra Publ./American Geophysical Union, Tokyo, 1987).
Irifune, T. & Ringwood, A. E. in High-Pressure Research in Mineral Physics. (eds Manghnani, M. H. & Syono, Y.) 231–242 (Terra Publ./American Geophysical Union, Tokyo, 1987).
Madon, M., Castex, J. & Peyronneau, J. Nature 342, 422–425 (1989).
Irifune, T., Fujino, K. & Ohtani, E. Nature 349, 409–411 (1991).
FitzGerald, J. D. & Ringwood, A. E. Phys. Chem. Miner. 18, 40–46 (1991).
Ahmed-Zaid, I. & Madon, M. Nature 353, 425–428 (1991).
Irifune, T. et al. in High-Pressure Research: Application to Earth and Planetary Sciences. (eds Syono, Y. & Manghnani, M. H.) 43–50 (Terra Publ./American Geophysical Union, Tokyo, 1992).
Irifune, T. & Ringwood, A. E. Earth planet. Sci. Lett. 117, 101–110 (1993).
Ringwood, A. E. in Advances in Earth Sciences, (ed. Hurley, P. M.) 287–356 (MIT Press, Cambridge, 1966).
Akaogi, M. & Akimoto, S. Phys. Earth planet. Inter. 19, 31–51 (1979).
Ito, E. & Takahashi, E. J. geophys. Res. 94, 10637–10646 (1989).
Kesson, S. E. & FitzGerald, J. D. Earth planet. Sci. Lett. 111, 229–240 (1991).
Ito, E. & Matsui, Y. Earth planet. Sci. Lett. 33, 443–450 (1978).
Yagi, T., Mao, H.-K. & Bell, P. M. Carnegie Inst. Wash. Yb. 77, 837–841 (1978).
Weng, K., Mao, H.-K. & Bell, P. M. Carnegie Inst. Wash. Yb. 81, 273–277 (1981).
Tamai, H. & Yagi, T. Phys. Earth planet. Inter. 54, 370–377 (1989).
Irifune, T., Susaki, J., Yagi, T. & Sawamoto, H. Geophys. Res. Lett. 16, 187–190 (1989).
Canil, D. Phys. Earth planet. Inter. (in the press).
Liu, L.-G. Earth planet. Sci. Lett. 36, 237–245 (1977).
O'Neill, B. & Jeanloz, R. Geophys. Res. Lett. 17, 1477–1480 (1990).
Fukao, Y. in High-Pressure Research (eds Manghnani, M. H. & Akimoto, S.) 151–161 (Academic, New York, 1977).
Dziewonski, A. & Anderson, D. L. Phys. Earth planet. Inter. 25, 297–356 (1981).
Kumazawa, M. Jap. J. Petrol. Mineral. Econ. Geol. Spec. Iss. 3, 239–247 (1981).
Liu, L.-G. Geochem. J. 16, 287–310 (1982).
Anderson, D. L. J. geophys. Res. 88, 41–52 (1983).
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Irifune, T. Absence of an aluminous phase in the upper part of the Earth's lower mantle. Nature 370, 131–133 (1994). https://doi.org/10.1038/370131a0
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DOI: https://doi.org/10.1038/370131a0
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