A dynamical model for the P1 - I1 phase transition in anorthite, CaAl2Si2O8 - I. Evidence from electron microscopy

AbstractElectron diffraction and electron microscopic evidence is presented for a dynamical and reversible $$P\bar 1 - I\bar 1$$ phase transition in anorthite at Tc=516 K. Antiphase boundaries with a displacement vector, R=1/2[111] become unstable at Tc, while other antiphase boundary loops with the same displacement vector are formed. These interfaces are very mobile and vibrate with a frequency which increases strongly with temperature. At temperatures considerably above Tc, a shimmering effect is observed on imaging in dark field using diffuse c reflections. These observations are in agreement with the interpretation of the high temperature body-centered phase as a statistical dynamical average of very small c type antiphase domains of primitive anorthite. We propose that the c type antiphase domains in primitive anorthite originate from ordered and anti-ordered configurations around Ca2+ ions at (ooo) and (oio) [likewise (zoo) and (zio)] positions. The dynamical model for the transition involves a two-stage mechanism: a softmode mechanism causing the aluminosilicate framework to approach body-centered symmetry, followed by an orderdisorder of the Ca2+ ion configurations. Close to Tc, statistical fluctuations set in and breathing motion type lattice vibrations of the aluminosilicate framework cause the configurations around Ca (ooo) and Ca(oio) [likewise Ca(zoo) and Ca(zio)] in the $$P\bar 1$$ configuration to dynamically interchange through an intermediate $$I\bar 1$$ configuration. The dynamical nature of the phase transition in anorthite is comparable to the α — β phase transition in quartz.