Milan Dopita scite author profile

Crystalline materials with broken inversion symmetry can exhibit a spontaneous electric polarization, which originates from a microscopic electric dipole moment. Long-range polar or anti-polar order of such permanent dipoles gives rise to ferroelectricity or antiferroelectricity, respectively. However, the recently discovered antiferroelectrics of fluorite structure (HfO2 and ZrO2) are different: A non-polar phase transforms into a polar phase by spontaneous inversion symmetry breaking upon the application of an electric field. Here, we show that this structural transition in antiferroelectric ZrO2 gives rise to a negative capacitance, which is promising for overcoming the fundamental limits of energy efficiency in electronics. Our findings provide insight into the thermodynamically forbidden region of the antiferroelectric transition in ZrO2 and extend the concept of negative capacitance beyond ferroelectricity. This shows that negative capacitance is a more general phenomenon than previously thought and can be expected in a much broader range of materials exhibiting structural phase transitions.

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Influence of annealing on the microstructure of commercial Mg alloy AZ31 after mechanical forming

Jäger

Lukáč

Gärtnerová

et al. 2006

Materials Science and Engineering: A

116

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Some consequences of the partial crystallographic coherence between nanocrystalline domains in Ti–Al–N and Ti–Al–Si–N coatings

et al. 2006

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Development of magnetic order in the pseudo-ternary series ErNi1−Cu Al

Prchal

Javorský

Sechovský

et al. 2004

Journal of Magnetism and Magnetic Materials

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Effect of Internal Interfaces on Hardness and Thermal Stability of Nanocrystalline Ti0.5Al0.5N Coatings

Rafaja

Wüstefeld

Baehtz

et al. 2010

Metall Mater Trans A

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The effect of microstructure on the thermal stability and hardness of the cathodic arc evaporated Ti 0.5 Al 0.5 N coatings was investigated with the aid of the in-situ high-temperature X-ray diffraction experiments, which were accompanied by high-resolution transmission electron microscopy (HRTEM) and nanoindentation measurements. The microstructure of the coatings was modified through the choice of the bias voltage in the deposition process. It was found that the bias voltage affects strongly the uniformity of the local distribution of titanium and aluminum in the coatings. The nonuniform distribution of the elements contributes to the formation of lattice strains at the crystallite and phase boundaries. The lattice strains at the crystallite boundaries increase the hardness of the coatings; the lattice strains at the phase boundaries improve their thermal stability. A certain nonuniformity of the distribution of the metallic species in the coatings is regarded as advantageous. However, a great nonuniformity in the distribution of the metallic species accelerates the degradation of the coatings at high temperatures. As a measure for the nonuniformity of the distribution of the atomic species in the as-deposited (Ti, Al) N samples, the stress-free lattice parameter of fcc-(Ti, Al) N is suggested.

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Milan Dopita

Antiferroelectric negative capacitance from a structural phase transition in zirconia

Influence of annealing on the microstructure of commercial Mg alloy AZ31 after mechanical forming

Some consequences of the partial crystallographic coherence between nanocrystalline domains in Ti–Al–N and Ti–Al–Si–N coatings

Development of magnetic order in the pseudo-ternary series ErNi1−Cu Al

Effect of Internal Interfaces on Hardness and Thermal Stability of Nanocrystalline Ti0.5Al0.5N Coatings

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