Nanocrystalline structure and strain in magnesium under extreme dynamic compression
Abstract
The study of materials behavior under extreme conditions is fundamental to science and modern technology. Fast ramp compression is a unique method for exploring materials behavior and phase transformations under extreme conditions. One unexplored feature of this method is the nanoscale structure of the material under dynamic compression. This leaves a gap in understanding the details of phase transformations under fast ramp compression. Here, we made a first step in the exploration by applying the Williamson-Hall (WH) analysis to X-ray diffraction data (XRD) measured in magnesium subjected to fast ramp compression at four pressures. We found that at P = 309 GPa magnesium in bcc-like phase has an average crystalline size D = (2.2 0.7) nm and microstrain = (-0.011 0.007). At P = 409 GPa, magnesium demonstrates D = (4.5 3) nm with = (-0.003 0.007). At P = 563 GPa, Fmmm magnesium has crystalline size D = (2.6 0.5) nm with microstrain = (-0.004 0.004). At P = 959 GPa, we revealed that sh-magnesium exhibits average size of D > 12 nm and relatively high value of microstrain = (0.011 0.002). In the result, we report the first microstructural evolution insights of magnesium under fast ramp compression.
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