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Mantle Convection and Surface Expressions


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can provide a more controlled compression than a membrane‐driven DAC (Evans et al., 2007; Jenei et al., 2019). The dynamic DAC has recently been combined with high‐resolution radiography to successfully measure small strains in an iron sample at high pressure (Hunt et al., 2018). Estimated total strains for compression in the DAC are ~0.3 (30%) and strain rates (albeit discontinuous) are on the order of 10−4s−1 (Marquardt & Miyagi, 2015). Recently, rotational DACs have been developed that allow large shear strains to be imposed at pressures in excess of 100 GPa (Azuma et al., 2018; Nomura et al., 2017).

      Small sample sizes in the DAC further limit its capabilities as a deformation device. Sample sizes are quite small in the DAC, generally 0.03–0.05 mm thick at the start of an experiment and on the order of a few hundredths of a millimeter to a few tenths of a millimeter in diameter. This yields corresponding sample volumes of ~10−2 mm3 to 10−5 mm3, but volumes become significantly reduced at high pressures. As a sufficient number of grains must be sampled to obtain statistically representative information, the upper limit of grain sizes feasible in the DAC is quite low. This makes studying the effect of changing grain size on rheology problematic in the DAC. One techniques that has been recently developed that somewhat alleviates this problem is the use of multigrain crystallography, which allows the use of coarse‐grained samples (Nisr et al., 2012). In spite of its many limitations, the DAC remains the only deformation device that can reach pressures covering the entire range of the lower mantle (Figure 2.1).

      2.3.2 Large‐Volume Deformation Devices

      The Rotational Drickamer Apparatus (RDA) is an opposed anvil device, where one anvil has the capability to rotate. Pressure and compressive stress are increased by advancing the anvils. When the desired pressure is reached, large shear strain can be induced by rotation of the anvil (Yamazaki & Karato, 2001a). The RDA can reach P‐T conditions of the upper lower mantle ~27 GPa at ~2100 K (Girard et al., 2016). The main advantages of the RDA are that it can reach higher pressures than other large‐volume techniques and can reach high shear strains. However, the RDA is limited to smaller samples than the above multianvil techniques and also has larger temperature and pressure gradients. Due to the fact that deformation is induced by rotation of the anvils, the RDA also has large strain gradients across the sample, though this is somewhat alleviated by using a doughnut‐shaped sample. Generally speaking, the large volume apparatuses are far superior to the DAC in terms of measuring rheological properties but lack the pressure range available in the DAC, and thus, currently these two types of techniques are complementary for understanding deformation of lower mantle phases.

      2.3.3 Texture and Strength Measurements in High‐Pressure Experiments

      For samples deformed in axial compression, lattice planes perpendicular to compression are more reduced in spacing relative to planes perpendicular to the radial direction (Singh, 1993; Singh et al., 1998). This is due to elastic strain imposed by the deformation device. If single crystal elastic properties are known, differential stress supported by the sample can be calculated from measured lattice strains (Singh, 1993; Singh et al., 1998). Stresses measured during these experiments can provide a lower bounds estimate for the flow strength of the material (Kavner & Duffy, 2001; Merkel et al., 2002). During plastic deformation, lattice strains may become systematically larger or smaller on various crystallographic planes, as stress is anisotropically relieved by dislocation motion. Frequently, in high‐pressure experiments, aggregate flow strength is taken to be an arithmetic mean of stresses calculated on the measured lattice plane. This method can be biased, depending on which lattices planes are measured. Lattice strain anisotropy does provide information on active deformation mechanisms and can be used to constrain slip system activities (Karato, 2009; Turner & Tomé, 1994). Texture development is an expression of plastic deformation and results from dislocation glide/creep and/or mechanical twinning. Texture is easily observed with radial x‐ray diffraction as systematic intensity variations along diffraction rings. By deconvoluting these intensity variations, textures can be measured in‐situ in DACs or large volume deformation devices (Wenk, Lonardelli, et al., 2006). For an example methodology of texture analysis from radial x‐ray diffraction the reader is referred to Wenk et al. (2014).