Search results for "value"

showing 10 items of 5321 documents

The fabric attractor

1997

Abstract The nature of fabric accumulation in high strain zones such as ductile shear zones depends on the nature and orientation of flow eigenvectors or apophyses. Some flow apophyses can act as ‘attractors’ of material lines or principal finite strain axes. This paper explains the nature of such attractors and discusses their significance and orientation in different monoclinic flow types. In ductile shear zones, strain values are high enough to show the effect of attractors in deformed rocks clearly. The concept of attractors can be used in deformation modelling, and can help in understanding the accumulation of deformation fabrics in homogeneous and inhomogeneous flow, e.g. around boudi…

Condensed Matter::Materials ScienceFlow (mathematics)Strain (chemistry)Finite strain theoryOrientation (geometry)AttractorGeologyGeotechnical engineeringGeometryDeformation (engineering)Shear zoneEigenvalues and eigenvectorsGeologyJournal of Structural Geology
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Magnetization states in ultrathin films with laterally modulated anisotropies

1998

Abstract Micromagnetic theory has been applied to a model system for ultrathin films with laterally modulated anisotropies, consisting of a periodic array of stripes with alternating uniaxial anisotropies. Despite of the discontinuous change of anisotropy, the magnetization direction only changes on a lateral scale given by the exchange length. If the width of one of the two alternating stripes is reduced below a critical value, the magnetization will switch into a uniform state. The variation of the critical width with period, anisotropy constants, exchange constant, and film thickness has been determined using an analytic approach. Non-uniform magnetization states and the magnetization re…

Condensed Matter::Materials ScienceMagnetizationMagnetic anisotropyMaterials scienceCondensed matter physicsPeriod (periodic table)MonolayerThin filmCondensed Matter PhysicsCritical valueAnisotropyMicromagneticsElectronic Optical and Magnetic MaterialsJournal of Magnetism and Magnetic Materials
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Depolarization Field and Properties of Thin Ferroelectric Films with Inclusion of the Electrode Effect

2005

The influence of metallic electrodes on the properties of thin ferroelectric films is considered in the framework of the Ginzburg-Landau phenomenological theory. The contribution of the electrodes with different screening lengths l s of carriers in the electrode material is included in the free-energy functional. The critical temperature T cl , the critical thickness of the film, and the critical screening length of the electrode at which the ferroelectric phase transforms into the paraelectric phase are calculated. The Euler-Lagrange equation for the polarization P is solved by the direct variational method. The results demonstrate that the film properties can be calculated by minimizing t…

Condensed Matter::Materials ScienceMaterials scienceCondensed matter physicsSolid-state physicsPhase (matter)ElectrodeDielectricCondensed Matter PhysicsPolarization (electrochemistry)Critical valueFerroelectricityElectronic Optical and Magnetic MaterialsPyroelectricityPhysics of the Solid State
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Algebraic value of the electrooptic coefficients and nature of charge carriers in batio3single crystals

1989

Abstract Some monodomain pure and Fe doped barium titanate monocrystals are studied. The algebraic values of the electrooptic coefficients r 13 and r 33 are evaluated using an interferometric method. Then, from energy transfer results it is possible to conclude that majority carriers are positive charges in all the samples.

Condensed Matter::Materials Sciencechemistry.chemical_compoundMaterials scienceCondensed matter physicschemistryFe dopedEnergy transferBarium titanateCharge carrierAlgebraic numberCondensed Matter PhysicsValue (mathematics)Electronic Optical and Magnetic MaterialsFerroelectrics
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Probabilities, States, Statistics

2016

In this chapter we clarify some important notions which are relevant in a statistical theory of heat: The definitions of probability measure, and of thermodynamic states are illustrated, successively, by the classical Maxwell-Boltzmann statistics, by Fermi-Dirac statistics and by Bose-Einstein statistics. We discuss observables and their eigenvalue spectrum as well as entropy and we calculate these quantities for some examples. The chapter closes with a comparison of statistical descriptions of classical and quantum gases.

Condensed Matter::Quantum GasesBinary entropy functionEntropy (statistical thermodynamics)StatisticsLaw of total probabilityObservableBlack-body radiationStatistical theoryEigenvalues and eigenvectorsMathematicsProbability measure
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The trapping condition and a new instability of the ion motion in the ion cyclotron resonance trap

1995

Abstract In analogy to the critical mass, m crit , a critical voltage, U crit , (and a general trapping parameter, π trap ) is defined, above which the ion motion in an ion cyclotron resonance (ICR) trap is unstable and the ions are lost from the trap. The theoretical values for the critical voltage are confirmed by experimental results. Singly charged gold cluster ions, Au n − , of several sizes, n = 50, 60, 76, 100, 110, and 145 (the latter corresponding to an ion mass of 28 560 u), were injected into an ICR trap, stored, and detected by axial ejection and single ion counting using a microchannel plate detector. During the storage period the trapping voltage, U , was varied for extended d…

Condensed Matter::Quantum GasesChemistryCyclotronTrappingPenning trapCritical valueFourier transform ion cyclotron resonanceIonlaw.inventionlawPhysics::Atomic PhysicsIon trapAtomic physicsSpectroscopyIon cyclotron resonanceInternational Journal of Mass Spectrometry and Ion Processes
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Pseudo-bosons and Riesz Bi-coherent States

2016

After a brief review on D-pseudo-bosons we introduce what we call Riesz bi-coherent states, which are pairs of states sharing with ordinary coherent states most of their features. In particular, they produce a resolution of the identity and they are eigenstates of two different annihilation operators which obey pseudo-bosonic commutation rules.

Condensed Matter::Quantum GasesIdentity (mathematics)Theoretical physicsAnnihilationRiesz representation theoremQuantum mechanicsCoherent statesCommutationEigenvalues and eigenvectorsMathematicsResolution (algebra)Boson
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Quantum critical point in a periodic Anderson model

2000

We investigate the symmetric Periodic Anderson Model (PAM) on a three-dimensional cubic lattice with nearest-neighbor hopping and hybridization matrix elements. Using Gutzwiller's variational method and the Hubbard-III approximation (which corresponds to the exact solution of an appropriate Falicov-Kimball model in infinite dimensions) we demonstrate the existence of a quantum critical point at zero temperature. Below a critical value $V_c$ of the hybridization (or above a critical interaction $U_c$) the system is an {\em insulator} in Gutzwiller's and a {\em semi-metal} in Hubbard's approach, whereas above $V_c$ (below $U_c$) it behaves like a metal in both approximations. These prediction…

Condensed Matter::Quantum GasesPhysicsStrongly Correlated Electrons (cond-mat.str-el)Quantum Monte CarloFOS: Physical sciencesCritical value01 natural sciences010305 fluids & plasmasCondensed Matter - Strongly Correlated ElectronsExact solutions in general relativityVariational methodQuantum critical pointQuantum mechanics0103 physical sciencesDensity of statesCondensed Matter::Strongly Correlated ElectronsStrongly correlated material010306 general physicsAnderson impurity modelPhysical Review B
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Three-mode two-boson Jaynes–Cummings model in trapped ions

2006

In this paper, we analyse a two-boson three-mode Jaynes–Cummings model which can be implemented in the context of trapped ions. The symmetries of the Hamiltonian are brought to light and analysed in detail in order to solve the eigenvalue problem. The calculation of the time evolution operator shows the possibility of realizing interesting applications, such as the generation of nonclassical states.

Condensed Matter::Quantum GasesStatistics and ProbabilityPhysicsSettore FIS/02 - Fisica Teorica Modelli E Metodi MatematiciJaynes–Cummings modelsuperposition (mathematics)modesGeneral Physics and AstronomyStatistical and Nonlinear PhysicsQuantum PhysicsSettore FIS/03 - Fisica Della MateriaIonsymbols.namesakeharmonic oscillatorModeling and SimulationQuantum mechanicsQuantum electrodynamicsHomogeneous spacesymbolsHamiltonian (quantum mechanics)Mathematical PhysicsEigenvalues and eigenvectorsBosonJournal of Physics A: Mathematical and Theoretical
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ChemInform Abstract: Tuning the Defect Configurations in Nematic and Smectic Liquid Crystalline Shells

2013

Thin liquid crystalline shells surrounding and surrounded by aqueous phases can be conveniently produced using a nested capillary microfluidic system, as was first demonstrated by Fernandez-Nieves et al. in 2007. By choosing particular combinations of stabilizers in the internal and external phases, different types of alignment, uniform or hybrid, can be ensured within the shell. Here, we investigate shells in the nematic and smectic phases under varying boundary conditions, focusing in particular on textural transformations during phase transitions, on the interaction between topological defects in the director field and inclusions in the liquid crystal (LC), and on the possibility to relo…

Condensed Matter::Soft Condensed MatterPhase transitionChemistryChemical physicsCapillary actionLiquid crystalPhase (matter)Shell (structure)General MedicineBoundary value problemRotationTopological defectChemInform
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