Your search keyword '"Kaisheva, Maria V"' showing total 6 results

1. Giant pressure-induced volume collapse in the pyrite mineral MnS2

Author

Kimber, Simon A. J., Salamat, Ashkan, Evans, Shaun R., Jeschke, Harald O., Muthukumar, Kaliappan, Tomic, Milan, Salvat-Pujol, Francesc, Valenti, Roser, Kaisheva, Maria V., Zizak, Ivo, and Chatterji, Tapan

Subjects

Condensed Matter - Strongly Correlated Electrons

Abstract

Dramatic volume collapses under pressure are fundamental to geochemistry and of increasing importance to fields as diverse as hydrogen storage and high-temperature superconductivity. In transition metal materials, collapses are usually driven by so-called spin-state transitions, the interplay between the single-ion crystal field and the size of the magnetic moment. Here we show that the classical S=5/2 mineral Hauerite undergoes an unprecedented 22 % collapse driven by a conceptually different magnetic mechanism. Using synchrotron x-ray diffraction we show that cold compression induces the formation of a disordered intermediate. However, using an evolutionary algorithm we predict a new structure with edge-sharing chains. This is confirmed as the thermodynamic groundstate using in situ laser heating. We show that magnetism is globally absent in the new phase, as low-spin quantum S=1/2 moments are quenched by dimerisation. Our results show how the emergence of metal-metal bonding can stabilise giant spin-lattice coupling in Earth's minerals., Comment: Published version, minor changes

Published

2013

2. The effect of metals and soil pH on the growth of Rhododendron and other alpine plants in limestone soil

Author

Kaisheva, Maria V. and Rankin, David W. H.

Subjects

583, Chemistry, Rhododendron, Horticulture

Abstract

Rhododendrons are economically important plants in horticulture, and many species are threatened in the wild by habitat degradation. It is therefore doubly important that their nutritional needs should be understood.

Published

2008

3. Giant pressure-induced volume collapse in the pyrite mineral MnS 2

Author

Kimber, Simon A. J., Salamat, Ashkan, Evans, Shaun R., Jeschke, Harald O., Muthukumar, Kaliappan, Tomić, Milan, Salvat-Pujol, Francesc, Valentí, Roser, Kaisheva, Maria V., Zizak, Ivo, and Chatterji, Tapan

Published

2014

4. The effect of metals and soil pH on the growth of Rhododendron and other alpine plants in limestone soil

Author

Kaisheva, Maria V and Rankin, David W H

Subjects

Chemistry, Rhododendron, Horticulture

Abstract

Rhododendrons are economically important plants in horticulture, and many species are threatened in the wild by habitat degradation. It is therefore doubly important that their nutritional needs should be understood.

Published

2008

5. Giant pressure-induced volume collapse in the pyrite mineral MnS2.

Author

Kimber, Simon A. J., Salamat, Ashkan, Evans, Shaun R., Jeschke, Harald O., Muthukumar, Kaliappan, Tomić, Milan, Salvat-Pujol, Francesc, Valenti, Roser, Kaisheva, Maria V., Zizak, Ivo, and Chatterji, Tapan

Subjects

PYRITES, GEOCHEMISTRY, HYDROGEN storage, SUPERCONDUCTIVITY, SYNCHROTRONS

Abstract

Dramatic volume collapses under pressure are fundamental to geochemistry and of increasing importance to fields as diverse as hydrogen storage and high-temperature superconductivity. In transition metal materials, collapses are usually driven by so-called spin-state transitions, the interplay between the single-ion crystal field and the size of the magnetic moment. Here we show that the classical S = 5/2 mineral hauerite (MnS2) undergoes an unprecedented (ΔV ∼22 %) collapse driven by a conceptually different magnetic mechanism. Using synchrotron X-ray diffraction we show that cold compression induces the formation of a disordered intermediate. However, using an evolutionary algorithm we predict a new structure with edge-sharing chains. This is confirmed as the thermodynamic ground state using in situ laser heating. We show that magnetism is globally absent in the new phase, as low-spin quantum S = 1/2 moments are quenched by dimerization. Our results show how the emergence of metal-metal bonding can stabilize giant spin-lattice coupling in Earth's minerals. [ABSTRACT FROM AUTHOR]

Published

2014

6. Giant pressure-induced volume collapse in the pyrite mineral MnS2.

Author

Kimber, Simon A. J., Salamat, Ashkan, Evans, Shaun R., Jeschke, Harald O., Muthukumar, Kaliappan, Tomić, Milan, Salvat-Pujol, Francesc, Valenti, Roser, Kaisheva, Maria V., Zizak, Ivo, and Chatterji, Tapan

Subjects

*PYRITES, *GEOCHEMISTRY, *HYDROGEN storage, *SUPERCONDUCTIVITY, *SYNCHROTRONS

Abstract

Dramatic volume collapses under pressure are fundamental to geochemistry and of increasing importance to fields as diverse as hydrogen storage and high-temperature superconductivity. In transition metal materials, collapses are usually driven by so-called spin-state transitions, the interplay between the single-ion crystal field and the size of the magnetic moment. Here we show that the classical S = 5/2 mineral hauerite (MnS2) undergoes an unprecedented (ΔV ∼22 %) collapse driven by a conceptually different magnetic mechanism. Using synchrotron X-ray diffraction we show that cold compression induces the formation of a disordered intermediate. However, using an evolutionary algorithm we predict a new structure with edge-sharing chains. This is confirmed as the thermodynamic ground state using in situ laser heating. We show that magnetism is globally absent in the new phase, as low-spin quantum S = 1/2 moments are quenched by dimerization. Our results show how the emergence of metal-metal bonding can stabilize giant spin-lattice coupling in Earth's minerals. [ABSTRACT FROM AUTHOR]

Published

2014