0000000000124149

AUTHOR

Malcolm Mcmahon

showing 6 related works from this author

Phase diagram of calcium at high pressure and high temperature

2018

Resistively heated diamond-anvil cells have been used together with synchrotron x-ray diffraction to investigate the phase diagram of calcium up to 50 GPa and 800 K. The phase boundaries between the Ca-I (fcc), Ca-II (bcc), and Ca-III (simple cubic, sc) phases have been determined at these pressure-temperature conditions, and the ambient temperature equation of state has been generated. The equation of state parameters at ambient temperature have been determined from the experimental compression curve of the observed phases by using third-order Birch-Murnaghan and Vinet equations. A thermal equation of state was also determined for Ca-I and Ca-II by combining the room-temperature Birch-Murn…

DiffractionEquation of stateMaterials sciencePhysics and Astronomy (miscellaneous)Thermodynamics02 engineering and technologyCubic crystal system01 natural sciencesThermal expansionPhysics::GeophysicsSynchrotronCondensed Matter::Materials SciencePhase (matter)0103 physical sciencesGeneral Materials Science010306 general physicsPhase diagramAlkaline earth metalTransitionsEquation-of-state021001 nanoscience & nanotechnologyX-ray crystallographyX-Ray-diffractionAlkaline-earth metals0210 nano-technology
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Equation of state and high-pressure/high-temperature phase diagram of magnesium

2014

The phase diagram of magnesium has been investigated to 211 GPa at 300 K, and to 105 GPa at 4500 K, by using a combination of x-ray diffraction and resistive and laser heating. The ambient pressure hcp structure is found to start transforming to the bcc structure at ∼45 GPa, with a large region of phase-coexistence that becomes smaller at higher temperatures. The bcc phase is stable to the highest pressures reached. The hcp-bcc phase boundary has been studied on both compression and decompression, and its slope is found to be negative and steeper than calculations have previously predicted. The laser-heating studies extend the melting curve of magnesium to 105 GPa and suggest that, at the h…

DiffractionPhase boundaryEquation of stateMaterials scienceCondensed matter physicsMagnesiumThermodynamicschemistry.chemical_elementCondensed Matter PhysicsElectronic Optical and Magnetic MaterialschemistryPhase (matter)X-ray crystallographyPhase diagramAmbient pressure
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Thallium under extreme compression

2016

We present a combined theoretical and experimental study of the high-pressure behavior of thallium. X-ray diffraction experiments have been carried out at room temperature up to 125 GPa using diamond-anvil cells, nearly doubling the pressure range of previous experiments. We have confirmed the hcp-fcc transition at 3.5 GPa and determined that the fcc structure remains stable up to the highest pressure attained in the experiments. In addition, HP-HT experiments have been performed up to 8 GPa and 700 K by using a combination of x-ray diffraction and a resistively heated diamond-anvil cell. Information on the phase boundaries is obtained, as well as crystallographic information on the HT bcc …

DiffractionEquation of stateMaterials scienceFOS: Physical sciencesThermodynamicschemistry.chemical_element02 engineering and technology01 natural sciencesPressure rangeAb initio quantum chemistry methodsPhysics - Chemical PhysicsPhase (matter)0103 physical sciencesGeneral Materials Science010306 general physicsChemical Physics (physics.chem-ph)Condensed Matter - Materials ScienceMaterials Science (cond-mat.mtrl-sci)021001 nanoscience & nanotechnologyCondensed Matter PhysicsCompression (physics)Condensed Matter - Other Condensed MatterchemistryThalliumOrthorhombic crystal system0210 nano-technologyOther Condensed Matter (cond-mat.other)Journal of Physics: Condensed Matter
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The phase diagram of Ti-6Al-4V at high-pressures and high-temperatures.

2020

Abstract We report results from a series of diamond-anvil-cell synchrotron x-ray diffraction and large-volume-press experiments, and calculations, to investigate the phase diagram of commercial polycrystalline high-strength Ti-6Al-4V alloy in pressure–temperature space. Up to ∼30 GPa and 886 K, Ti-6Al-4V is found to be stable in the hexagonal-close-packed, or α phase. The effect of temperature on the volume expansion and compressibility of α–Ti-6Al-4V is modest. The martensitic α → ω (hexagonal) transition occurs at ∼30 GPa, with both phases coexisting until at ∼38–40 GPa the transition to the ω phase is completed. Between 300 K and 844 K the α → ω transition appears to be independent of te…

Materials scienceTriple pointThermodynamics02 engineering and technology021001 nanoscience & nanotechnologyCondensed Matter Physics01 natural sciencesOmegaHysteresisMartensitePhase (matter)0103 physical sciencesX-ray crystallographyGeneral Materials ScienceCrystallite010306 general physics0210 nano-technologyPhase diagramJournal of physics. Condensed matter : an Institute of Physics journal
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The high-pressure, high-temperature phase diagram of cerium

2020

Abstract We present an experimental study of the high-pressure, high-temperature behaviour of cerium up to ∼22 GPa and 820 K using angle-dispersive x-ray diffraction and external resistive heating. Studies above 820 K were prevented by chemical reactions between the samples and the diamond anvils of the pressure cells. We unambiguously measure the stability region of the orthorhombic oC4 phase and find it reaches its apex at 7.1 GPa and 650 K. We locate the α-cF4–oC4–tI2 triple point at 6.1 GPa and 640 K, 1 GPa below the location of the apex of the oC4 phase, and 1–2 GPa lower than previously reported. We find the α-cF4 → tI2 phase boundary to have a positive gradient of 280 K (GPa)−1, less…

Phase boundaryMaterials scienceTriple pointThermodynamicsDiamondchemistry.chemical_element02 engineering and technologyengineering.material021001 nanoscience & nanotechnologyCondensed Matter Physics01 natural sciencesCeriumchemistryPhase (matter)0103 physical sciencesX-ray crystallographyengineeringGeneral Materials ScienceOrthorhombic crystal system010306 general physics0210 nano-technologyPhase diagramJournal of Physics: Condensed Matter
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High-pressure/high-temperature phase diagram of zinc

2018

The phase diagram of zinc (Zn) has been explored up to 140 GPa and 6000K, by combining optical observations, x-ray diffraction, and ab initio calculations. In the pressure range covered by this study, Zn is found to retain a hexagonal close-packed (hcp) crystal symmetry up to the melting temperature. The known decrease of the axial ratio (c/a) of the hcp phase of Zn under compression is observed in x-ray diffraction experiments from 300K up to the melting temperature. The pressure at which c/a reaches root 3 (approximate to 10GPa) is slightly affected by temperature. When this axial ratio is reached, we observed that single crystals of Zn, formed at high temperature, break into multiple pol…

DiffractionPhase transitionMaterials sciencemeltingPOWDER DIFFRACTIONELECTRONIC TOPOLOGICAL TRANSITIONSThermodynamicschemistry.chemical_elementFOS: Physical sciences02 engineering and technologyCrystal structureZincDIAMOND-ANVIL CELL01 natural scienceshigh temperatureCondensed Matter::Materials ScienceX-RAY-DIFFRACTIONPhase (matter)Condensed Matter::Superconductivity0103 physical sciencesGeneral Materials Science010306 general physicsMELTING CURVEPhase diagramCondensed Matter - Materials ScienceAxial ratioSYNCHROTRONab initio calculationszincMaterials Science (cond-mat.mtrl-sci)021001 nanoscience & nanotechnologyCondensed Matter PhysicsCompression (physics)EQUATION-OF-STATEhigh pressurechemistryx-ray diffractionphase transitionZNMETALS0210 nano-technologyRESISTANCE
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