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1. Periclase deforms more slowly than bridgmanite under mantle conditions

   https://doi.org/10.1038/s41586-022-05410-9  

   Cordier, Patrick; Gouriet, Karine; Weidner, Timmo; Van Orman, James; Castelnau, Olivier; Jackson, Jennifer M.; Carrez, Philippe (January 2023, Nature)

   Abstract Transport of heat from the interior of the Earth drives convection in the mantle, which involves the deformation of solid rocks over billions of years. The lower mantle of the Earth is mostly composed of iron-bearing bridgmanite MgSiO 3 and approximately 25% volume periclase MgO (also with some iron). It is commonly accepted that ferropericlase is weaker than bridgmanite 1 . Considerable progress has been made in recent years to study assemblages representative of the lower mantle under the relevant pressure and temperature conditions 2,3 . However, the natural strain rates are 8 to 10 orders of magnitude lower than in the laboratory, and are still inaccessible to us. Once the deformation mechanisms of rocks and their constituent minerals have been identified, it is possible to overcome this limitation thanks to multiscale numerical modelling, and to determine rheological properties for inaccessible strain rates. In this work we use 2.5-dimensional dislocation dynamics to model the low-stress creep of MgO periclase at lower mantle pressures and temperatures. We show that periclase deforms very slowly under these conditions, in particular, much more slowly than bridgmanite deforming by pure climb creep. This is due to slow diffusion of oxygen in periclase under pressure. In the assemblage, this secondary phase hardly participates in the deformation, so that the rheology of the lower mantle is very well described by that of bridgmanite. Our results show that drastic changes in deformation mechanisms can occur as a function of the strain rate. 

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2. Earth’s mantle composition revealed by mantle plumes

   https://doi.org/10.1038/s43017-023-00467-0  

   Weis, Dominique; Harpp, Karen S; Harrison, Lauren N; Boyet, Maud; Chauvel, Catherine; Farnetani, Cinzia G; Finlayson, Valerie A; Lee, Kanani_K M; Parai, Rita; Shahar, Anat; et al (September 2023, Nature Reviews Earth & Environment)
3. Linking lowermost mantle structure, core-mantle boundary heat flux and mantle plume formation

   https://doi.org/10.1016/j.pepi.2018.01.010  

   Li, Mingming; Zhong, Shijie; Olson, Peter (January 2018, Physics of the Earth and Planetary Interiors)
4. Coupled deep-mantle carbon-water cycle: Evidence from lower-mantle diamonds

   https://doi.org/10.1016/j.xinn.2021.100117  

   Wang, Wenzhong; Tschauner, Oliver; Huang, Shichun; Wu, Zhongqing; Meng, Yufei; Bechtel, Hans; Mao, Ho-Kwang (May 2021, The Innovation)
5. The root to the Galápagos mantle plume on the core-mantle boundary

   https://doi.org/10.26443/seismica.v1i1.197  

   Cottaar, Sanne; Martin, Carl; Li, Zhi; Parai, Rita (October 2022, Seismica)

   Ultra-low velocity zones (ULVZs) are thin anomalous patches on the boundary between the Earth's core and mantle, revealed by their effects on the seismic waves that propagate through them. Here we map a broad ULVZ near the Galápagos hotspot using shear-diffracted waves. Forward modelling assuming a cylindrical shape shows the patch is ~600 km wide, ~20 km high, and its shear velocities are ~25% reduced. The ULVZ is comparable to other broad ULVZs mapped on the core-mantle boundary near Hawaii, Iceland, and Samoa.  Strikingly, all four hotspots where the mantle plume appears rooted by these ‘mega-ULVZs’, show similar anomalous isotopic signatures in He, Ne, and W in their ocean island basalts. This correlation suggests mega-ULVZs might be primordial or caused by interaction with the core, and some material from ULVZs is entrained within the plume. For the Galápagos, the connection implies the plume is offset to the west towards the base of the mantle. 

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