Search results for "High Pressure"

showing 10 items of 894 documents

Cinnabar phase in ZnSe at high pressure

2001

We have performed an energy-dispersive x-ray-diffraction experiment on ${\mathrm{ZnSe}}_{1\ensuremath{-}x}{\mathrm{Te}}_{x}$ alloys under high pressure with $x=0,$ 0.05, 0.1, and 0.2. In the downstroke a hexagonal phase appears. We suggest that this phase is cinnabar, whose stability range decreases as the Te content is reduced. The analysis of the whole series of compositions enables us to establish its lattice parameters in ZnSe $(a=3.785\AA{}$ and $c=8.844\AA{}$ at 10.5 GPa). The extinction of some diffraction peaks also suggests that the internal parameters u and $v$ are close to 0.5, indicating that the cinnabar phase in ZnSe is similar to that observed in GaAs and ZnTe.

DiffractionMaterials scienceOpticsCinnabarbusiness.industryHigh pressureLattice (order)Hexagonal phaseAnalytical chemistrybusinessPhysical Review B
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GaS and InSe equations of state from single crystal diffraction

2007

We have performed single crystal angle dispersive X-ray diffraction at high pressure in order to investigate the GaS and InSe equations of state. We situate the transition from β-GaS to GaS-II at 2 7 0 3. ± . GPa. In the InSe experiment we locate the beginning of the phase transition at 7.6 ± 0.6 GPa. The equations of state of β-GaS ( 0 43 27 0 06V = . ± . Å 3 , 37 2 GPaB = ± , 5 2B = .¢ ), GaS-II ( 0 42 4 0 2V = . ± . Å 3 , 50 3 GPaB = ± and 4 3 0 3B = . ± .¢ ) and γ-InSe ( 0 58 4 0 2V = . ± . Å 3 , 24 3 GPaB = ± and 8 6 0 8B = . ± .¢ ) are discussed and compared with the results of an ab-initio calculation.

DiffractionPhase transitionChemistryScattering02 engineering and technology021001 nanoscience & nanotechnologyCondensed Matter Physics01 natural sciencesSingle Crystal DiffractionElectronic Optical and Magnetic MaterialsCrystallographyAb initio quantum chemistry methodsHigh pressure[PHYS.COND.CM-GEN]Physics [physics]/Condensed Matter [cond-mat]/Other [cond-mat.other]0103 physical sciencesX-ray crystallographyPACS : 61.10.Nz 61.82.Fk 62.50.+p 64.30.+t010306 general physics0210 nano-technologySingle crystal
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Observation of the Cinnabar Phase in ZnSe at High Pressure

2002

In this paper we describe the results of an energy dispersive X-ray diffraction experiment carried out in the ZnSe 1 m x Te x alloy and pure ZnSe under high pressure. In the downstroke the cinnabar phase is observed between the rocksalt and the zincblende phases. The analysis of the whole series of compositions ( x =0, 0.05, 0.1 and 0.2) enables us to establish its lattice parameters in ZnSe ( a =3.785 + and c =8.844 + at 10.5 GPa). The X-ray diffraction pattern simulation suggests that the internal parameters u and v are close to 0.5, indicating that the cinnabar phase in ZnSe is similar to that observed in GaAs and ZnTe. The cinnabar's stability range decreases as the Te content is reduce…

DiffractionPhase transitionCrystallographyMaterials scienceCinnabarHigh pressureLattice (order)AlloyX-ray crystallographyAnalytical chemistryengineeringengineering.materialCondensed Matter PhysicsHigh Pressure Research
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High-pressure phase transformations in NdVO4 under hydrostatic, conditions: a structural powder x-ray diffraction study

2019

Room temperature angle dispersive powder x-ray diffraction experiments on zircon-type NdVO4 were performed for the first time under quasi-hydrostatic conditions up to 24.5 GPa. The sample undergoes two phase transitions at 6.4 and 19.9 GPa. Our results show that the first transition is a zircon-to-scheelite-type phase transition, which has not been reported before, and contradicts previous non-hydrostatic experiments. In the second transition, NdVO4 transforms into a fergusonite-type structure, which is a monoclinic distortion of scheelite-type. The compressibility and axial anisotropy of the different polymorphs of NdVO4 are reported. A direct comparison of our results with former experime…

DiffractionPhase transitionEquation of stateMaterials scienceThermodynamics02 engineering and technologyzircon01 natural scienceszircon; scheelite; x-ray diffraction; high pressure; equation of state; phase transition; orthovanadatescheeliteorthovanadatePhase (matter)0103 physical sciencesGeneral Materials Science010306 general physicsAnisotropyequation of state021001 nanoscience & nanotechnologyCondensed Matter Physicshigh pressurex-ray diffractionphase transitionX-ray crystallographyCompressibility0210 nano-technologyMonoclinic crystal system
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High-pressure study of the behavior of mineral barite by x-ray diffraction

2011

In this paper, we report the angle-dispersive x-ray diffraction data of barite, BaSO 4, measured in a diamond-anvil cell up to a pressure of 48 GPa, using three different fluid pressure-transmitting media (methanol-ethanol mixture, silicone oil, and He). Our results show that BaSO 4 exhibits a phase transition at pressures that range from 15 to 27 GPa, depending on the pressure media used. This indicates that nonhydrostatic stresses have a crucial role in the high-pressure behavior of this compound. The new high-pressure (HP) phase has been solved and refined from powder data, having an orthorhombic P2 12 12 1 structure. The pressure dependence of the structural parameters of both room- and…

DiffractionPhase transitionMaterials scienceHigh-pressureAnalytical chemistryDensityHigh pressure (Technology)BaSO4symbols.namesakeBariteCationsPhase (matter)Barium compoundsCompostos de bariRamanMineralTemperatureOxidesTecnologia de les altes pressionsCondensed Matter PhysicsX-ray diffractionElectronic Optical and Magnetic MaterialsFISICA APLICADAHigh pressureTransitionX-ray crystallographysymbolsOrthorhombic crystal systemRaman spectroscopyBASO4Physical Review B
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First-Order Isostructural Phase Transition Induced by High Pressure in Fe(IO3)3

2020

The high-pressure (HP) behavior of Fe(IO3)3 was studied up to 35 GPa using powder X-ray diffraction, infrared micro-spectroscopy, and ab initio density-functional theory calculations. Fe(IO3)3 show...

DiffractionPhase transitionMaterials scienceInfraredAb initio02 engineering and technology010402 general chemistry021001 nanoscience & nanotechnologyFirst order01 natural sciences0104 chemical sciencesSurfaces Coatings and FilmsElectronic Optical and Magnetic MaterialsCrystallographyGeneral EnergyHigh pressurePhysical and Theoretical ChemistryIsostructural0210 nano-technologyThe Journal of Physical Chemistry C
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Pressure-induced amorphization of YVO4:Eu3+ nanoboxes

2016

A structural transformation from the zircon-type structure to an amorphous phase has been found in YVO4:Eu3+ nanoboxes at high pressures above 12.7 GPa by means of x-ray diffraction measurements. However, the pair distribution function of the high-pressure phase shows that the local structure of the amorphous phase is similar to the scheelite-type YVO4. These results are confirmed both by Raman spectroscopy and Eu3+ photoluminescence which detect the phase transition to a scheelite-type structure at 10.1 and 9.1 GPa, respectively. The irreversibility of the phase transition is observed with the three techniques after a maximum pressure in the upstroke of around 20 GPa. The existence of two …

DiffractionPhase transitionMaterials sciencePhotoluminescenceAnalytical chemistryBioengineeringNanotechnology02 engineering and technologyNanocrystal010402 general chemistry01 natural sciencessymbols.namesakePhase (matter)General Materials ScienceElectrical and Electronic EngineeringMechanical EngineeringPair distribution functionGeneral Chemistry021001 nanoscience & nanotechnologyAmorphous phaseAmorphization0104 chemical sciencesHigh pressureNanocrystalMechanics of MaterialsFISICA APLICADAsymbols0210 nano-technologyRaman spectroscopy
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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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High-pressure structural investigation of several zircon-type orthovanadates

2009

Room temperature angle-dispersive x-ray diffraction measurements on zircon-type EuVO4, LuVO4, and ScVO4 were performed up to 27 GPa. In the three compounds we found evidence of a pressure-induced structural phase transformation from zircon to a scheelite-type structure. The onset of the transition is near 8 GPa, but the transition is sluggish and the low- and high-pressure phases coexist in a pressure range of about 10 GPa. In EuVO4 and LuVO4 a second transition to a M-fergusonite-type phase was found near 21 GPa. The equations of state for the zircon and scheelite phases are also determined. Among the three studied compounds, we found that ScVO4 is less compressible than EuVO4 and LuVO4, b…

DiffractionStructural phaseCondensed Matter - Materials ScienceMaterials sciencebusiness.industryMaterials Science (cond-mat.mtrl-sci)FOS: Physical sciencesType (model theory)Condensed Matter PhysicsElectronic Optical and Magnetic MaterialsGeophysics (physics.geo-ph)Pressure rangePhysics - Geophysicschemistry.chemical_compoundCrystallographyOpticschemistryHigh pressureScheelitePhase (matter)businessZircon
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High-pressure X-ray diffraction study of EuWO4 to 12 GPa

2005

In-situ high-pressure X-ray diffraction studies were performed on EuWO4 to 12 GPa. We found that EuWO4 transforms from the tetragonal I41/a structure to the monoclinic I2/a structure at 8.5(5) GPa, being this phase transition re- versible. No other structural change is detected up to 12 GPa. The EOS of EuWO4 is determined from the pressure–volume data. (© 2005 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim)

DiffractionTetragonal crystal systemPhase transitionCrystallographyStructural changeChemistryHigh pressureX-ray crystallographyCrystal structureCondensed Matter PhysicsElectronic Optical and Magnetic MaterialsMonoclinic crystal systemphysica status solidi (b)
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