Keywords: بلورهای صوتی; Phononic crystals; Metamaterials; Tunable band gaps; Architected materials; Vibration mitigation;
مقالات ISI بلورهای صوتی (ترجمه نشده)
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Keywords: بلورهای صوتی; Wave motion; Periodically layered composites; Piezoelectricity; Semi-analytical method; Phononic crystals; Functionally graded materials; Band-gaps; Pass bands;
Keywords: بلورهای صوتی; Asymptotic analysis; Imperfect interface; Elastodynamics; Phononic crystals; Transfer matrix method;
Keywords: بلورهای صوتی; Phononic crystals; Multistable; Wave directionality; Band gap;
Keywords: بلورهای صوتی; Phononic crystals; Interface conditions; Elastic wave propagation; Band structures; Eigenvalue problems; Radial basis functions;
Keywords: بلورهای صوتی; Phononic crystals; Fluid structure interaction; Band gap; Mass-redistributed finite element method (MR-FEM);
Keywords: بلورهای صوتی; Dielectric elastomers; Wave propagation; Phononic crystals; Tunable materials;
Keywords: بلورهای صوتی; Phononic crystals; Leaky Bloch waves; Attenuation; Band structure; Finite element method; Plane wave expansion method;
Keywords: بلورهای صوتی; Phononic crystals; Cavity resonance; Symmetry reduction; Defect mode; Biomedical sensor; Point of care technologies; Acoustic wave sensor;
Keywords: بلورهای صوتی; Photonic crystals; Phononic crystals; Surface wave; Acousto-optical coupling; Optomechanics;
Keywords: بلورهای صوتی; Tube arrays; Phononic crystals; Acoustic radiation; Cold point defect;
Keywords: بلورهای صوتی; Phononic crystals; Band gap; Topological optimization; Bi-directional evolutionary structural optimization;
Keywords: بلورهای صوتی; Tube arrays; Phononic crystals; Acoustic radiation; Oblique incident; Sound transmission characteristics;
Keywords: بلورهای صوتی; Phononic crystals; Evanescent waves; Bi-directional evolutionary structural optimization (BESO); Band gap;
Keywords: بلورهای صوتی; Phononic crystals; Wave; Hyperelasticity; Transformation; Band-gap;
Keywords: بلورهای صوتی; Unidirectional acoustic transmission; Phononic crystals; Partial band gap; Topological optimization; Bi-directional evolutionary structural optimization (BESO);
Keywords: بلورهای صوتی; Phononic crystals; Aperiodicity; Wave localization; Localization factor; Transfer matrix method;
Keywords: بلورهای صوتی; Layered materials; Elastic waves; Finite deformations; Band gaps; Phononic crystals;
Keywords: بلورهای صوتی; Phononic crystals; Phononic band gaps; “Analogous rigid mode”; Localized resonance mechanism; Double-sided stubbed composite PC plate; Expansion of lower-frequency locally resonant band gaps
Keywords: بلورهای صوتی; Phononic crystals; Hierarchical; Wave propagation; Honeycombs; Band gaps;
Keywords: بلورهای صوتی; Piezoelectric resonators; Phononic crystals; Piezoelectric transducers;
Keywords: بلورهای صوتی; Phononic crystals; Band gaps; Defect modes; Fiber Bragg gratings (FBGs); Flexural waves;
Keywords: بلورهای صوتی; Parametric loudspeaker; Spurious sound; Phononic crystals; Gaussian-beam expansion technique
Keywords: بلورهای صوتی; Photonic crystals; Phononic crystals; Phoxonic crystals; Sensor; Surface wave;
Keywords: بلورهای صوتی; Colloidal crystals; Acoustic assembly; Phononic crystals; Acoustic metamaterials; Cristaux colloïdaux; Assemblée acoustique; Cristaux phononiques; Métamatériaux acoustiques;
Keywords: بلورهای صوتی; RBF collocation method; Phononic crystals; Stability; Band structures; Interface models
Keywords: بلورهای صوتی; Phononic crystals; Acoustic band gaps; Auxetics; Tunable elastic properties
Keywords: بلورهای صوتی; Band gap; Phononic crystals; Finite element method (FEM); Alpha finite element method (αFEM);
Keywords: بلورهای صوتی; Band gaps; Jerusalem cross slot; Phononic crystals; Finite element method
Keywords: بلورهای صوتی; Multiband; Wave filtering; Waveguide; Hierarchical composites; Phononic crystals
Keywords: بلورهای صوتی; Band structures; Phononic crystals; Finite element method; Material's periodic arrangement; Local resonance;
Keywords: بلورهای صوتی; Phononic band gaps; Phononic crystals; Inertial amplification; Three-dimensional lattice; 3D printer
Keywords: بلورهای صوتی; Phononic crystals; Boundary element method; Interface effect; Band structure; Band gap; Periodic;
Keywords: بلورهای صوتی; Enhanced energy harvesting; Phononic crystals; Acoustic metamaterials; Electromagnetic metamaterials; Thermal metamaterials
Keywords: بلورهای صوتی; Vibration; Acoustics; Stress waves; Phononic crystals; Layered materials;
Keywords: بلورهای صوتی; Functionally graded materials; Phononic crystals; Laminates; Elastic waves; Wave transmission; Band-gaps; Transfer matrix method
Keywords: بلورهای صوتی; Crack; Localization; Resonance; Boundary integral equation method; Band-gaps; Phononic crystals
Keywords: بلورهای صوتی; Acoustic coating; Phononic crystals; Soft elastic material; Effective medium approximation; Finite element method;
A general multiscale framework for the emergent effective elastodynamics of metamaterials
Keywords: بلورهای صوتی; Computational multiscale analysis; Homogenization; Micromorphic continua; Floquet-Bloch transform; Acoustic metamaterials; Phononic crystals;
A BEM for band structure and elastic wave transmission analysis of 2D phononic crystals with different interface conditions
Keywords: بلورهای صوتی; Boundary element method; Phononic crystals; Interface conditions; Eigenvalue problem; Band structures; Elastic wave transmission;
Ultrasonic bandgaps in 3D-printed periodic ceramic microlattices
Keywords: بلورهای صوتی; Phononic crystals; Ceramics; Additive manufacturing; Bandgaps; Wave propagation; Finite elements method;
Nonlinear waves in lattice materials: Adaptively augmented directivity and functionality enhancement by modal mixing
Keywords: بلورهای صوتی; Nonlinear waves; Harmonic generation; Mode hopping; Modal mixing; Spatial Directivity; Phononic crystals;
Inverse design of high-Q wave filters in two-dimensional phononic crystals by topology optimization
Keywords: بلورهای صوتی; Filters; Phononic crystals; Topology optimization; Q factor; Fano resonances; Symmetric resonance;
Harvesting vibrations via 3D phononic isolators
Keywords: بلورهای صوتی; Phononic crystals; Phononic shields; Phononic diode; Trapping vibrations; Cristaux phononiques; Boucliers phononiques; Diode phononique; Piégeage de vibrations;
Phoxonic crystals and cavity optomechanics
Keywords: بلورهای صوتی; Phononic crystals; Phoxonics; Optomechanics; Theory; Photoelasticity; Moving interface effect; Cristaux phononiques; Phoxonique; Optomécanique; Théorie; Photoélasticité; Effet d'interface en mouvement;
Generalized Bloch's theorem for viscous metamaterials: Dispersion and effective properties based on frequencies and wavenumbers that are simultaneously complex
Keywords: بلورهای صوتی; Damped waves; Complex dispersion; Complex band structure; Phononic crystals; Acoustic metamaterials; Periodic materials; Ondes amorties; Dispersion complexe; Structure de bandes complexe; Cristaux phononiques; Métamatériaux acoustiques; Matériaux péri
BEM-based analysis of elastic banded material by using a contour integral method
Keywords: بلورهای صوتی; BEM; Phononic crystals; Eigenvalue problem; Contour integral method
Enhanced plane wave expansion analysis for the band structure of bulk modes in two-dimensional high-contrast solid–solid phononic crystals
Keywords: بلورهای صوتی; Phononic crystals; Plane wave expansion; Bandgap; High contrast; Inverse rule; Laurents rule
Band gaps in the low-frequency range based on the two-dimensional phononic crystal plates composed of rubber matrix with periodic steel stubs
Keywords: بلورهای صوتی; Band gaps; Rubber matrix; Finite element method; Phononic crystals
Broadband characteristics of vibration energy harvesting using one-dimensional phononic piezoelectric cantilever beams
Keywords: بلورهای صوتی; Broadband vibrations; Energy harvesting; Piezoelectric cantilever beams; Phononic crystals; Vibration band gap; Finite element simulation