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Abstract: The similar electronic structures of Bi3+ and Pb2+ have motivated researchers to explore bismuth-based perovskite compounds, which in the past decade has been further fuelled by the demand for developing lead-free piezoceramics. The difficulty in stabilizing the perovskite phase in bismuth based compounds has directed most research activities towards exploring two main compounds - multiferroic BiFeO3 and relaxor ferroelectric Na1/2Bi1/2TiO3 and their derivatives. In recent years, quenching these materials from the sintering temperature or from the paraelectric phase (above the Curie temperature, Tc) has resulted in a plethora of fundamentally interesting and technologically relevant advances, including enhanced thermal depolarization temperature, high Tc, giant strain and control over the atomic structure and electrical conductivity at the domain wall. In this contribution, a brief overview of quenching piezoceramics is presented, with majority of the discussion encompassing salient features of quenching lead-free perovskite structured Na1/2Bi1/2TiO3- and BiFeO3- based materials. For each material system, the influence of quenching on phase transitions, domain switching behavior and electromechanical properties are presented, apart from outlining the current understanding of the underlying mechanisms. The review provides guidelines for further exploration of the quenching strategy for improving the functionality of Bi-based piezoceramics.

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Abstract: The high-pressure and high-temperature phase diagram of chromium has been investigated both experimentally (in situ), using a laser-heated diamond-anvil cell technique coupled with synchrotron powder X-ray diffraction, and theoretically, using ab initio density-functional theory simulations. In the pressure–temperature range covered experimentally (up to 90 GPa and 4500 K, respectively) only the solid body-centred-cubic and liquid phases of chromium have been observed. Experiments and computer calculations give melting curves in agreement with each other that can both be described by the Simon–Glatzel equation 𝑇𝑚(𝑃)=2136𝐾(1+𝑃/25.9)0.41 T m ( P ) = 2136 K ( 1 + P / 25.9 ) 0.41 . In addition, a quasi-hydrostatic equation of state at ambient temperature has been experimentally characterized up to 131 GPa and compared with the present simulations. Both methods give very similar third-order Birch–Murnaghan equations of state with bulk moduli of 182–185 GPa and respective pressure derivatives of 4.74–5.15. According to the present calculations, the obtained melting curve and equation of state are valid up to at least 815 GPa, at which pressure the melting temperature is 9310 K. Finally, from the obtained results, it was possible to determine a thermal equation of state of chromium valid up to 65 GPa and 2100 K.

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Abstract: The lanthanide and actinide metals have complex electronic and magnetic behaviour at high pressures and low temperatures, respectively, owing to the f electrons buried within the atoms participating in the bonding of those metals. As one traverses the lanthanide series with increasing Z at ambient conditions, each element adds one electron to the 4f shell, starting with cerium (Ce) and ending with a full 4f electron shell in lutetium (Lu). This thesis focuses on the trivalent lanthanides, which are considered to be all the lanthanides except Ce, europium (Eu) and ytterbium (Yb), and their structural systematics at high pressures. The trivalent lanthanides exhibit a common, pressure-induced, structural phase transition sequence: hexagonal close-packed (hcp) ! Sm-type or -Sm ! double-hcp (dhcp) ! face-centred cubic (fcc) ! distorted-fcc (dfcc) ! \volume-collapsed". This sequence is thought to arise from the 5s ! 5d transfer of electrons, and, at ultra-high pressures, from the 4f electrons becoming delocalised and then participating in the bonding of these elements, leading to volume-collapsed phases with low-symmetry structures. However, there is still debate over the exact structures of the low-symmetry collapsed phases. This thesis describes x-ray di raction studies of the high-pressure structures of the collapsed phases of six trivalent lanthanide elements (neodymium (Nd), samarium (Sm), praseodymium (Pr), gadolinium (Gd), terbium (Tb) and dysprosium (Dy)), and also yttrium (Y) { a rare-earth element. Using diamond anvil cell (DAC) techniques and x-ray powder di raction at the Diamond Light Source and PETRA-III synchrotrons, the structures of the collapsed phases of six of the seven elements are found to be face-centred orthorhombic, spacegroup Fddd, with either 8 atoms (Nd and Sm) or 16 atoms (Gd, Tb, Dy and Y) in the unit cell. The 8-atom structure (oF8) is the same as that seen previously in the actinides plutonium (Pu), americium (Am), curium (Cm) and californium (Cf), greatly strengthening the structural relationships between the 4f lanthanides and the 5f actinides. The 16-atom structure (oF16) found in Gd, Tb, Dy and Y is previously unknown in the elements, but, along with the oF8 structure, and hP3 structure seen in Nd and Sm at lower pressures, it is a member of a new structural family comprising di erent stackings of quasi-hcp layers. This thesis also describes higher-pressure studies with the aim of determining the structural systematics of the post-oF8/oF16 phases. Pr and Nd have been shown to exhibit the -uranium ( -U) structure, oC4, in their collapsed phases. In Pr, a primitive orthorhombic structure was previously reported above 147 GPa, the post- -U phase, a structure not seen in any other element. This thesis shows that the true structure is body-centred tetragonal, the same as the highest-pressure phase seen in the neighbouring lanthanide Ce, and also in the actinides thorium (Th) and uranium (U), suggesting that it is the \next" structure in the transition sequence of the trivalent lanthanides. This work contained in this thesis completely rewrites the structural behaviour of the trivalent lanthanide elements at high-pressure and reveals that the highpressure behaviour of the lanthanide and actinide metals is much more similar than previously believed.

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Abstract: The emergence of antimicrobial resistant strains bacteria and a decline in the discovery of new antibiotics has led to the idea of combining various antimicrobials to treat resistant strains and/or polymicrobial infections. Metal oxide-doped glasses have been extensively investigated for their antimicrobial potential; however to date, most experiments have focused on single metal species in isolation. The present study investigates the antimicrobial potential of sodium calcium phosphates (P2O5)50(Na2O)20(CaO)30–X(MO)X, where M is cobalt, copper, or zinc as single species. In addition, this work studied the effect of co-doping glasses containing two different metal ions (Co + Cu, Co + Zn, and Cu + Zn). The antimicrobial efficacy of all glasses was tested against Gram-positive (Staphylococcus aureus) and Gram-negative (Escherichia coli) bacterial strains, as well as a fungal strain (Candida albicans). Minimum inhibitory and bactericidal concentrations and time kill/synergy assays were used to assess the antimicrobial activity. An enhanced antimicrobial effect, at 5 mg/mL concentration, was exhibited by cobalt, copper, and zinc oxide glasses alone and in combinations. A synergistic antimicrobial effect was observed by Cu + Co and Cu + Zn against E. coli and Cu + Zn against S. aureus.

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Abstract: Using synchrotron X-ray total scattering and empirical potential structure refinement modelling, we studied systematically in operando condition the disorder-to-order local atomic structure transition in a pure Al and a dilute Al-0.4Sc alloy melt in the temperature range from 690 °C to 657 °C. In the liquid state, icosahedral short-range ordered Sc-centred Al polyhedrons form and most of them with Al coordination number of 10–12. As the melt is cooled to the semisolid state, the most Sc-centred polyhedrons become more connected atom clusters via vertex, edge and face-sharing. These polyhedrons exhibit partially icosahedral and partially face-centred-cubic symmetry. The medium-range ordered Sc-centred clusters with face-sharing are proved to be the “precursors” of the L12 Al3Sc primary phases in the liquid-solid coexisting state.