Your search keyword '"Guenneau, Sebastien"' showing total 360 results

1. Stochastic cloaking: concealing a region from diffusive particles

Author

Roberts, Connor, Zhang, Ziluo, Rojas, Helder, Bo, Stefano, Escudero, Carlos, Guenneau, Sebastien, and Pruessner, Gunnar

Subjects

Condensed Matter - Materials Science, Condensed Matter - Statistical Mechanics

Abstract

We present a novel class of cloaking in which a region of space is concealed from an ensemble of diffusing particles whose individual trajectories are governed by a stochastic (Langevin) equation. In particular, we simulate how different interpretations of the Langevin equation affect the cloaking performance of an annular single-layer invisibility cloak of smoothly varying diffusivity in two dimensions. Near-perfect cloaking is achieved under the Ito convention, indicated by the cloak preventing particles from accessing an inner core while simultaneously preserving the particle density outside the cloak relative to simulations involving no protected region (and no cloak). Even better cloaking performance can be achieved by regularising the singular behaviour of the cloak -- which we demonstrate through two different approaches. These results establish the foundations of ``stochastic cloaking'', which we believe to be a significant milestone following that of optical and thermal cloaking., Comment: 12 pages (6 pages main), 4 figures (2 figures main)

Published

2024

2. Propagation and non-reciprocity in time-modulated diffusion through the lens of high-order homogenization

Author

Touboul, Marie, Lombard, Bruno, Assier, Raphaël, Guenneau, Sébastien, and Craster, Richard

Subjects

Mathematics - Analysis of PDEs, Mathematics - Numerical Analysis

Abstract

The homogenization procedure developed here is conducted on a laminate with periodic space-time modulation on the fine scale: at leading order, this modulation creates convection in the low-wavelength regime if both parameters are modulated. However, if only one parameter is modulated, which is more realistic, this convective term disappears and one recovers a standard diffusion equation with effective homogeneous parameters; this does not describe the non-reciprocity and the propagation of the field observed from exact dispersion diagrams. This inconsistency is corrected here by considering second-order homogenization which results in a non-reciprocal propagation term that is proved to be non-zero for any laminate and verified via numerical simulation. The same methodology is also applied to the case when the density is modulated in the heat equation, leading therefore to a corrective advective term which cancels out non-reciprocity at the leading order but not at the second order.

Published

2024

3. Platonic quasi-normal modes expansion

Author

Vial, Benjamin, Sabaté, Marc Martí, Wiltshaw, Richard, Guenneau, Sébastien, and Craster, Richard V.

Subjects

Condensed Matter - Materials Science, Mathematical Physics, Physics - Applied Physics

Abstract

Elastic wave manipulation using large arrays of resonators is driving the need for advanced simulation and optimization methods. To address this we introduce and explore a robust framework for wave control: Quasi-normal modes (QNMs). Specifically we consider the problem for thin elastic plates, where the Green's function formalism is well known and readily exploited to solve multiple scattering problems. By studying the associated nonlinear eigenvalue problem we derive a dispersive QNM expansion, providing a reduced-order model for efficient forced response computations which reveals physical insight into the resonant mode excitation. Furthermore, we derive eigenvalue sensitivities with respect to resonator parameters and apply a gradient-based optimization to design quasi-bound states in the continuum and position eigenfrequencies precisely in the complex plane. Scattering simulations validate our approach in structures such as graded line arrays and quasi-crystals. Drawing on QNM concepts from electromagnetism we demonstrate significant advances in elastic metamaterials, highlighting their potential for tailored wave manipulation.

Published

2024

4. Robust Quasi-Bound States in the continuum: Accidental and Symmetry-Protected Variants in Dielectric Metasurfaces

Author

Mangach, Hicham, Belkacem, Abdelhaq, Achaoui, Younes, Bouzid, Abdenbi, Gralak, Boris, and Guenneau, Sebastien

Subjects

Condensed Matter - Materials Science, Physics - Optics

Abstract

Recently, man-made dielectric materials composed of finite-sized dielectric constituents have emerged as a promising platform for quasi-bound states in the continuum (QBICs). These states allow for an extraordinary confinement of light within regions smaller than the wavelength scale. Known for their exceptional quality factors, they have become crucial assets across a diverse array of applications. Given the circumstances, there is a compelling drive to find meta-designs that can possess multiple QBICs. Here, we demonstrate the existence of two different types of QBICs in silicon-based metasurfaces: accidental QBIC and symmetry-protected QBIC. The accidental QBIC evinces notable resilience to variations in geometrical parameters and symmetry, underscoring its capacity to adeptly navigate manufacturing tolerances while consistently upholding a distinguished quality factor of $10^5$. Conversely, the symmetry-protected QBIC inherently correlates with the disruption of unit cell symmetry. As a result, a phase delay yields an efficient channel for substantial energy transference to the continuum, endowing this variant with an exceedingly high quality factor, approaching $10^8$. Moreover, the manifestation of these QBICs stems from the intricate interplay among out-of-plane electric and magnetic dipoles, alongside in-plane quadrupoles exhibiting odd parities.

Published

2024

5. Isospectral open cavities and gratings

Author

Cominelli, Sebastiano, Vial, Benjamin, Guenneau, Sébastien, and Craster, Richard V.

Subjects

Physics - Applied Physics, Physics - Classical Physics

Abstract

Open cavities are often an essential component in the design of ultra-thin subwavelength metasurfaces and a typical requirement is that cavities have precise, often low frequency, resonances whilst simultaneously being physically compact. To aid this design challenge we develop a methodology to allow isospectral twinning of reference cavities with either smaller or larger ones, enforcing their spectra to coincide so that open resonators are identical in terms of their complex eigenfrequencies. For open systems the spectrum is not purely discrete and real, and we pay special attention to the accurate twinning of leaky modes associated with complex valued eigenfrequencies with an imaginary part orders of magnitude lower than the real part. We further consider twinning of 2D gratings, and model these with Floquet-Bloch conditions along one direction and perfectly matched layers in the other one; complex eigenfrequencies of special interest are located in the vicinity of the positive real line and further depend upon the Bloch wavenumber. The isospectral behaviour is illustrated, and quantified, throughout by numerical simulation using finite element analysis.

Published

2023

6. High-order homogenisation of the time-modulated wave equation: non-reciprocity for a single varying parameter

Author

Touboul, Marie, Lombard, Bruno, Assier, Raphaël, Guenneau, Sébastien, and Craster, Richard V

Subjects

Physics - Classical Physics

Abstract

Laminated media with material properties modulated in space and time in the form of travelling waves have long been known to exhibit non-reciprocity. However, when using the method of low frequency homogenisation, it was so far only possible to obtain non-reciprocal effective media when both material properties are modulated in time, in the form of a Willis-coupling (or bi-anisotropy in electromagnetism) model. If only one of the two properties is modulated in time, while the other is kept constant, it was thought impossible for the method of homogenisation to recover the expected non-reciprocity since this Willis-coupling coefficient then vanishes. Contrary to this belief, we show that effective media with a single time-modulated parameter are non-reciprocal, provided homogenization is pushed to the second order. This is illustrated by numerical experiments (dispersion diagrams and time-domain simulations) for a bilayered modulated medium.

Published

2023

7. An innovative clay metaBrick-based motif to enhance thermal and acoustic insulation

Author

Lemkalli, Brahim, Bensallam, Saad, Kadic, Muamer, Guenneau, Sébastien, Jakjoud, Hicham, Mir, Abdellah, and Achaoui, Younes

Subjects

Condensed Matter - Materials Science, Physics - Applied Physics

Abstract

Metamaterials have gained popularity in recent years as a promising avenue for producing innovative materials with distinctive properties that offer unprecedented features. In this study, we address the thermal and acoustic challenges of building materials. We numerically and experimentally investigate a clay metaBrick, which is an innovative metamaterial design based on the existing hollow brick that has shown strong sound and thermal performances. We evaluate the acoustic and thermal characteristics of the clay metaBrick, including sound transmission and heat resistance, using the finite element method. Furthermore, we validate the results experimentally by investigating the behaviors of the wall built on metaBricks in two tests: sound and thermal. We contrast the findings of the metaBrick based wall with performances of a standard hollow brick wall. The metaBrick offers enhanced acoustic and thermal insulation properties compared to the standard brick, with a compressive strength above standards required in the building materials., Comment: 16 pages, 10 figures

Published

2023

8. Bi-functional metamaterial based on Helmholtz resonators for sound and heat insulation

Author

Lemkalli, Brahim, Fellah, Zine El Abiddine, Guenneau, Sébastien, Lamzoud, Khalid, Mir, Abdellah, and Achaoui, Younes

Subjects

Condensed Matter - Materials Science, Physics - Applied Physics

Abstract

Over the last few decades, both heat and broadband sound reduction have become increasingly significant as a result of concerns about the environment and noise pollution. In order to address this challenge, we provide a finite element analysis study of an acoustic metamaterial panel consisting of a unit cell made of two Helmholtz Resonators with a guide in between. These panels can attenuate and control both sound propagation and heat flux. For noise pollution in a building, we first determine the geometric dimension that corresponds to the operative frequency range. Furthermore, we investigate the sound transmission loss of the proposed panel as a function of the periodicity of an array of unit cells. Additionally, we investigate the thermal flux induced by the panel, especially within a 24-hour period. The simulation results show that the proposed panel provides a level of sound attenuation within the frequency range of 400 Hz to 2.5 kHz, as well as interesting heat protection. The structure is compared to panels made up of a homogeneous medium and without Helmholtz resonators., Comment: 7 pages, 10 figures

Published

2023

9. High-frequency homogenization for periodic dispersive media

Author

Touboul, Marie, Vial, Benjamin, Assier, Raphaël, Guenneau, Sébastien, and Craster, Richard

Subjects

Physics - Classical Physics, Mathematical Physics, Physics - Optics

Abstract

High-frequency homogenization is used to study dispersive media, containing inclusions placed periodically, for which the properties of the material depend on the frequency (Lorentz or Drude model with damping, for example). Effective properties are obtained near a given point of the dispersion diagram in frequency-wavenumber space. The asymptotic approximations of the dispersion diagrams, and the wavefields, so obtained are then cross-validated via detailed comparison with finite element method simulations in both one and two dimensions.

Published

2023

10. Electromagnetic cloak design with mono-objective and bi-objective optimizers: seeking the best tradeoff between protection and invisibility

Author

Aznavourian, Ronald, Demesy, Guillaume, Guenneau, Sébastien, and Marot, Julien

Subjects

Physics - Computational Physics

Abstract

We revisit the design of cloaks, without resorting to any geometric transform. Cancellation techniques and anomalous resonances have been applied for this purpose. Instead of a deductive reasoning, we propose a novel mono-objective optimization algorithm, namely a ternary grey wolf algorithm, and we adapt a bi-objective optimization algorithm. Firstly, the proposed chaotic ternary grey wolf algorithm searches three-valued spaces for all permittivity values in the cloak while minimizing the summation of a protection criterion and an invisibility criterion. Secondly, a bi-objective genetic algorithm is adapted to find pairs of optimal values of invisibility and protection.

Published

2023

11. Subwavelength pulse focusing and perfect absorption in the Maxwell fisheye

Author

Lefebvre, Gautier, Dubois, Marc, Achaoui, Younes, Ing, Ros Kiri, Fink, Mathias, Guenneau, Sébastien, and Sebbah, Patrick

Subjects

Physics - Classical Physics, Condensed Matter - Other Condensed Matter

Abstract

Maxwell's fisheye is a paradigm for an absolute optical instrument with a refractive index deduced from the stereographic projection of a sphere on a plane. We investigate experimentally the dynamics of flexural waves in a thin plate with a thickness varying according to the Maxwell fisheye index profile and a clamped boundary. We demonstrate subwavelength focusing and temporal pulse compression at the image point. This is achieved by introducing a sink emitting a cancelling signal optimally shaped using a time-reversal procedure. Perfect absorption and outward going wave cancellation at the focus point are demonstrated. The time evolution of the kinetic energy stored inside the cavity reveals that the sink absorbs energy out of the plate ten times faster than the natural decay rate.

Published

2023

12. Fundamentals of Acoustic Metamaterials

Author

Guenneau, Sébastien R. L., Craster, Richard V., Hull, Robert, Series Editor, Jagadish, Chennupati, Series Editor, Kawazoe, Yoshiyuki, Series Editor, Kruzic, Jamie, Series Editor, Mooradian, Arshag D., Series Editor, Osgood Jr., Richard, Series Editor, Parisi, Jürgen, Series Editor, Pohl, Udo W., Series Editor, Sakaki, Hiroyuki, Series Editor, Seong, Tae-Yeon, Series Editor, Uchida, Shin-ichi, Series Editor, Wang, Zhiming M., Series Editor, Warlimont, Hans, Series Editor, Zunger, Alex, Series Editor, Craster, Richard, editor, and Guenneau, Sébastien, editor

Published

2024

13. Cloaking Liquid Surface Waves and Plasmon Polaritons

Author

Kadic, Muamer, Farhat, Mohamed, Guenneau, Sébastien R. L., Quidant, Romain, Enoch, Stefan, Hull, Robert, Series Editor, Jagadish, Chennupati, Series Editor, Kawazoe, Yoshiyuki, Series Editor, Kruzic, Jamie, Series Editor, Mooradian, Arshag D., Series Editor, Osgood Jr., Richard, Series Editor, Parisi, Jürgen, Series Editor, Pohl, Udo W., Series Editor, Sakaki, Hiroyuki, Series Editor, Seong, Tae-Yeon, Series Editor, Uchida, Shin-ichi, Series Editor, Wang, Zhiming M., Series Editor, Warlimont, Hans, Series Editor, Zunger, Alex, Series Editor, Craster, Richard, editor, and Guenneau, Sébastien, editor

Published

2024

14. Polarization State Conversion through Chiral Butterfly Meta-Structure

Author

Mangach, Hicham, Achaoui, Younes, Kadic, Muamer, Bouzid, Abdenbi, Guenneau, Sébastien, and Zeng, Shuwen

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Materials Science, Physics - Classical Physics

Abstract

The recent emergence of chirality in mechanical metamaterials has revolutionized the field, enabling achievements in wave propagation and polarization control. Despite being an intrinsic feature of some molecules and ubiquitous in our surroundings, the incorporation of chirality into mechanical systems has only gained widespread recognition in the last few years. The extra degrees of freedom induced by chirality has propelled the study of systems to new heights, leading to a better understanding of the physical laws governing these systems. In this study, we present a structural design of a butterfly meta-structure that exploits the chiral effect to create a 3D chiral butterfly capable of inducing a rotation of 90{\deg} in the plane of polarization, enabling a switch between various polarization states within a solid material. Furthermore, our numerical investigation using Finite Element Analysis (FEA) has revealed an unexpected conversion of compressional movement to transverse movement within these structures, further highlighting the transformative potential of chirality in mechanical metamaterials. Thus, revealing an additional degree of freedom that can be manipulated, namely the polarization state., Comment: 7 Pages, 11 figures

Published

2023

15. The emergence of low-frequency dual Fano resonances in chiral twisting metamaterials

Author

Lemkalli, Brahim, Kadic, Muamer, Badri, Youssef El, Guenneau, Sébastien, Mir, Abdellah, and Achaoui, Younes

Subjects

Physics - Applied Physics, Condensed Matter - Materials Science

Abstract

In the current work, through a finite element analysis, we demonstrate that a configuration of chiral cells having syndiotactic symmetry provides dual Fano resonances at low frequency. From the phononic dispersion and transmission response, we compare the signature provided by a composite made of chiral cells to the ones of homogeneous medium, isotactic nonchiral, and isotactic chiral beams. The study results in an innovative design of a mechanical metamaterial that induces the Fano resonance at low frequency with a relatively high quality factor. This might be a significant step forward for mechanical wave filtering and detection. Performances have been evaluated using a sensor that will be implemented as a thermometer., Comment: 7 pages, 5 figures

Published

2023

16. Seismic Waves Shielding Using Spherical Matryoshka-Like Metamaterials

Author

Lemkalli, Brahim, Guenneau, Sébastien, Badri, Youssef El, Kadic, Muamer, Mangach, Hicham, Mir, Abdellah, Achaoui, Younes, Kacprzyk, Janusz, Series Editor, Gomide, Fernando, Advisory Editor, Kaynak, Okyay, Advisory Editor, Liu, Derong, Advisory Editor, Pedrycz, Witold, Advisory Editor, Polycarpou, Marios M., Advisory Editor, Rudas, Imre J., Advisory Editor, Wang, Jun, Advisory Editor, Ben Ahmed, Mohamed, editor, Boudhir, Anouar Abdelhakim, editor, El Meouche, Rani, editor, and Karaș, İsmail Rakıp, editor

Published

2024

17. Longitudinal-Twist Wave Converter based on Chiral Metamaterials

Author

Lemkalli, Brahim, Kadic, Muamer, Badri, Youssef El, Guenneau, Sébastien, Mir, Abdellah, and Achaoui, Younes

Subjects

Physics - Applied Physics, Physics - Classical Physics

Abstract

Advances in material architectures have enabled endowing materials with exotic attributes not commonly available in the conventional realm of mechanical engineering. Twisting, a mechanism whereby metamaterials are used to transform static axial load into twist motion, is of particular interest to this study. Herein, computations based on the finite element method, corroborated by an analytical approach derived from applying Lagrange's equations to a monoatomic spring-mass system, are employed to explore the longitudinal-twist (L-T) conversion exhibited by a chiral tetragonal-beam metamaterial. Firstly, we perform an eigenvalue analysis taking into account the polarization states to highlight the potential contribution of the longitudinal mode in the L-T conversion. We contrast the twisting behavior of the chiral cell with that of other homogeneous medium, octagonal-tube, and non-chiral cells. Moreover, we demonstrate the influence of the cell's chirality on the L-T conversion using both time-domain and frequency-domain studies. The findings indicate that at least a portion of the longitudinally propagating wave is transformed into twist throughout a broad frequency range and even quasi-totally converted at distinct frequencies., Comment: 7 pages, 5 figures

Published

2022

18. Mapping of Elastic Properties of Twisting Metamaterials onto Micropolar Continuum using Static Calculations

Author

Lemkalli, Brahim, Kadic, Muamer, Badri, Youssef El, Guenneau, Sébastien, Bouzid, Abdenbi, and Achaoui, Younes

Subjects

Physics - Applied Physics, Condensed Matter - Materials Science

Abstract

Recent developments in the engineering of metamaterials have brought forth a myriad of mesmerizing mechanical properties that do not exist in ordinary solids. Among these, twisting metamaterials, acoustical chirality, or Willis coupling are sample-size dependent. The purpose of this work is, first, to examine the mechanical performance of a new twisting cubic metamaterial. Then, we perform a comparative investigation of its twisting behavior using the finite element method on microstructure elements computation, an analytical model, and we compare them to Eringen micropolar continuum. Notably, the results of the three models are in good qualitative and quantitative agreements. Finally, a systematic comparison of dispersion relations was made for the continuum and for the microstructures with different sizes in unit cells as final proof of perfect mapping., Comment: 9 pages, 5 figures

Published

2022

19. Dynamic cloaking of a diamond-shaped hole in elastic plate

Author

Tang, Kun, Luz, Eitam, Amram, David, Kadysz, Luna, Guenneau, Sebastien, and Sebbah, Patrick

Subjects

Physics - Classical Physics, Physics - Applied Physics

Abstract

Invisibility cloaks for flexural waves have been mostly examined in the continuous-wave regime, while invisibility is likely to deteriorate for short pulses. Here, we propose the practical realization of a unidirectional invisibility cloak for flexural waves based on an area-preserving coordinate transformation. Time-resolved experiments reveal how the invisibility cloak deviates a pulsed plane-wave from its initial trajectory, and how the initial wavefront perfectly recombines behind the cloak, leaving the diamond-shaped hole invisible, notwithstanding the appearance of a forerunner. Three-dimensional full-elasticity simulations support our experimental observations.

Published

2022

20. Transformation twinning to create isospectral cavities

Author

Lenz, Simon V., Guenneau, Sébastien, Drinkwater, Bruce W., Craster, Richard V., and Holderied, Marc W.

Subjects

Condensed Matter - Materials Science, Mathematical Physics, Physics - Optics

Abstract

Bounded domains have discrete eigenfrequencies/spectra, and cavities with different boundaries and areas have different spectra. A general methodology for isospectral twinning, whereby the spectra of different cavities are made to coincide, is created by combining ideas from across physics including transformation optics, inverse problems and metamaterial cloaking. We twin a hexagonal drum with a deformed hexagonal drum using a non-singular coordinate transform that adjusts the deformed shape by mapping a near boundary domain to a zone of heterogeneous anisotropic medium. Splines define the mapping zone for twinning these two drums and we verify isospectrality by finite element analysis., Comment: 6 pages, 3 figures

Published

2022

21. Asymmetric Heat Transfer with Linear Conductive Metamaterials

Author

Su, Yishu, Li, Ying, Qi, Minghong, Guenneau, Sebastien, Li, Huagen, and Xiong, Jian

Subjects

Physics - Applied Physics

Abstract

Asymmetric heat transfer systems, often referred to as thermal diodes or thermal rectifiers, have garnered increasing interest due to their wide range of application possibilities. Most of those previous macroscopic thermal diodes either resort to nonlinear thermal conductivities with strong temperature dependence that may be quite limited by or fixed in natural materials or rely on active modulation that necessitated auxiliary energy payloads. Here, we establish a straightforward strategy of passively realizing asymmetric heat transfer with linear conductive materials. The strategy also introduces a new interrogative perspective on the design of asymmetric heat transfer utilizing nonlinear thermal conductivity, correcting the misconception that thermal rectification is impossible with separable nonlinear thermal conductivity. The nonlinear perturbation mode can be versatilely engineered to produce an effective and wide-ranging perturbation in the heat conduction, which imitates and bypasses intrinsic thermal nonlinearity constraints set by naturally occurring counterparts. Independent experimental characterizations of surface thermal radiation and thermal convection verified that the heat exchange between a graded linear thermal metamaterial and the ambient can be tailored to achieve macroscopic asymmetric heat transfer. Our work is envisaged to inspire conceptual models for heat transfer control, serving as a robust and convenient platform for advanced thermal management, thermal computation, and heat transport.

Published

2022

22. Neolithic stone settlements as locally resonant metasurfaces

Author

Brûlé, Stéphane, Ungureanu, Bogdan, Enoch, Stefan, and Guenneau, Sébastien

Subjects

Physics - Geophysics, Condensed Matter - Materials Science, Physics - Computational Physics

Abstract

We study the dynamic surface response of neolithic stone settlements obtained with seismic ambient noise techniques near the city of Carnac in French Brittany. Surprisingly, we find that menhirs (neolithic human size standing alone granite stones) with an aspect ratio between 1 and 2 periodically arranged atop a thin layer of sandy soil laid on a granite bedrock, exhibit fundamental resonances in the range of 10 to 25 Hz. We propose an analogic Kelvin-Voigt viscoelastic model that explains the origin of such low frequency resonances. We further explore low frequency filtering effect with full wave finite element simulations. Our numerical results confirm the bending nature of fundamental resonances of the menhirs and further suggest additional resonances of rotational and longitudinal nature in the frequency range 25 to 50 Hz. Our study thus paves the way for large scale seismic metasurfaces consisting of granite stones periodically arranged atop a thin layer of regolith over a bedrock, for ground vibration mitigation in earthquake engineering., Comment: 6 pages, 7 figures

Published

2022

23. Two-scale cut-and-projection convergence for quasiperiodic monotone operators

Author

Wellander, Niklas, Guenneau, Sebastien, and Cherkaev, Elena

Subjects

Mathematics - Analysis of PDEs, Condensed Matter - Materials Science, Mathematical Physics

Abstract

Averaging certain class of quasiperiodic monotone operators can be simplified to the periodic homogenization setting by mapping the original quasiperiodic structure onto a periodic structure in a higher dimensional space using cut-and projection method. We characterize cut-and-projection convergence limit of the nonlinear monotone partial differential operator $-\mathrm{div} \; \sigma\left({\bf x},\frac{{\bf R}{\bf x}}{\eta}, \nabla u_\eta\right)$ for a bounded sequence $u_\eta$ in $W^{1,p}_0(\Omega)$, where $1

Published

2022

24. High-Quality Resonances in Quasi-Periodic Clusters of Scatterers for Flexural Waves

Author

Martí-Sabaté, Marc, Guenneau, Sébastien, and Torrent, Dani

Subjects

Physics - Classical Physics, Nonlinear Sciences - Pattern Formation and Solitons

Abstract

Multiple scattering theory is applied to the study of clusters of point-like scatterers attached to a thin elastic plate and arranged in quasi-periodic distributions. Two type of structures are specifically considered: the twisted bilayer and the quasi-periodic line. The former consists in a couple of two-dimensional lattices rotated a relative angle, so that the cluster forms a moir\'e pattern. The latter can be seen as a periodic one-dimensional lattice where an incommensurate modulation is superimposed. Multiple scattering theory allows for the fast an efficient calculation of the resonant modes of these structures as well as for their quality factor, which is thoroughly analyzed in this work. The results show that quasi-periodic structures present a large density of states with high quality factors, being therefore a promising way for the design of high quality wave-localization devices.

Published

2022

25. Active exterior cloaking for the 2D Helmholtz equation with complex wavenumbers and application to thermal cloaking

Author

Cassier, Maxence, DeGiovanni, Trent, Guenneau, Sébastien, and Vasquez, Fernando Guevara

Subjects

Mathematics - Analysis of PDEs, 35J05, 31B10, 35K05, 65M80

Abstract

We design sources for the two-dimensional Helmholtz equation that can cloak an object by cancelling out the incident field in a region, without the sources completely surrounding the object to hide. As in previous work for real positive wavenumbers, the sources are also determined by the Green identities. The novelty is that we prove that the same approach works for complex wavenumbers which makes it applicable to a variety of media, including media with dispersion, loss and gain. Furthermore, by deriving bounds on Graf's addition formulas with complex arguments, we obtain new estimates that allow to quantify the quality of the cloaking effect. We illustrate our results by applying them to achieve active exterior cloaking for the heat equation., Comment: 32 pages, 11 figures

Published

2022

26. Transformation design of in-plane elastic cylindrical cloaks, concentrators and lenses

Author

Brun, Michele and Guenneau, Sebastien

Subjects

Condensed Matter - Materials Science

Abstract

We analyse the elastic properties of a class of cylindrical cloaks deduced from linear geometric transforms ${\bf x} \to {\bf x}'$ in the framework of the Milton-Briane- Willis cloaking theory [New Journal of Physics 8, 248, 2006]. More precisely, we assume that the mapping between displacement fields ${\bf u}({\bf x}) \to {\bf u}'({\bf x}')$ is such that ${\bf u}'({\bf x}') = {\bf A}^{-t}{\bf u}({\bf x})$, where ${\bf A}$ is either the transformation gradient $F_{ij} = \partial x'_i/ \partial x_j$ or the second order identity tensor ${\bf I}$. The nature of the cloaks under review can be three-fold: some of them are neutral for a source located a couple of wavelengths away; other lead to either a mirage effect or a field confinement when the source is located inside the concealment region or within their coated region (some act as elastic concentrators squeezing the wavelength of a pressure or shear polarized incident plane wave in their core); a last category of cloaks is classified as an elastic counterpart of electromagnetic perfect cylindrical lenses. The former two categories require either rank-4 elastic tensor and rank-2 density tensor and additional rank-3 and 2 positive definite tensors $({\bf A} = {\bf F})$ or a rank 4 elasticity tensor and a scalar density $({\bf A} = {\bf I})$ with spatially varying positive values. However, the latter example further requires that all rank-4, 3 and 2 tensors be negative definite $({\bf A} = {\bf F})$ or that the elasticity tensor be negative definite (and non fully symmetric) as well as a negative scalar density $({\bf A} = {\bf I})$. We provide some illustrative numerical examples with the Finite Element package Comsol Multiphysics when ${\bf A}$ is the identity.

Published

2021

27. The emergence of low-frequency dual Fano resonances in chiral twisting metamaterials

Author

Lemkalli, Brahim, Kadic, Muamer, El Badri, Youssef, Guenneau, Sébastien, Mir, Abdellah, and Achaoui, Younes

Published

2024

28. Phonon transmission through a nonlocal metamaterial slab

Author

Chen, Yi, Wang, Ke, Kadic, Muamer, Guenneau, Sebastien, Wang, Changguo, and Wegener, Martin

Published

2023

29. Time-domain investigation of a cylindrical acoustic external cloak

Author

Guenneau, Sebastien, Lombard, Bruno, and Bellis, Cedric

Subjects

Physics - Computational Physics, Condensed Matter - Materials Science, Mathematics - Numerical Analysis

Abstract

Space folding techniques based on non-monotonic transforms lead to a new class of cylindrical isotropic acoustic cloaks with a constant negative density and a spatially varying negative bulk modulus. We consider an external cloak consisting of a core with a positive definite density matrix and a positive compressibility, and a shell with simultaneously negative density and compressibility. Such a core-shell resonant system creates a virtual folded region outside the shell. To handle such negative physical parameters in the time-domain, a two-step strategy is used: (i) assuming resonant (Drude-type) effective parameters in the frequency-domain; (ii) returning to the time-domain by applying the formalism of the auxiliary fields. We numerically show that, at the designed central frequency, scattering of a cylindrical pressure wave incident upon a finite set of small rigid obstacles is drastically reduced after a lapse of time, when they are placed in the close neighborhood of the external cloak. However, at short times, the external cloak behaves rather like a superscatterer: the cloak itself scatters more than the set of scatterers., Comment: 5 pages, 6 figures

Published

2020

30. Acoustic topological circuitry in square and rectangular phononic crystals

Author

Laforge, Nicolas, Wiltshaw, Richard, Craster, Richard V., Laude, Vincent, Martínez, Julio Andrés Iglesias, Dupont, Guillaume, Guenneau, Sébastien, Kadic, Muamer, and Makwana, Mehul P.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

We systematically engineer a series of square and rectangular phononic crystals to create experimental realisations of complex topological phononic circuits. The exotic topological transport observed is wholly reliant upon the underlying structure which must belong to either a square or rectangular lattice system and not to any hexagonal-based structure. The phononic system chosen consists of a periodic array of square steel bars which partitions acoustic waves in water over a broadband range of frequencies (~0.5 MHz). An ultrasonic transducer launches an acoustic pulse which propagates along a domain wall, before encountering a nodal point, from which the acoustic signal partitions towards three exit ports. Numerical simulations are performed to clearly illustrate the highly resolved edge states as well as corroborate our experimental findings. To achieve complete control over the flow of energy, power division and redirection devices are required. The tunability afforded by our designs, in conjunction with the topological robustness of the modes, will result in their assimilation into acoustical devices.

Published

2020

31. Bilayer thermal metadevices that mold transient heat flows

Author

Ji, Qingxiang, Zhang, Qi, Guenneau, Sébastien, Kadic, Muamer, and Wang, Changguo

Published

2024

32. Active Thermal Cloaking and Mimicking

Author

Cassier, Maxence, DeGiovanni, Trent, Guenneau, Sébastien, and Vasquez, Fernando Guevara

Subjects

Mathematics - Analysis of PDEs, Physics - Applied Physics, 31B10, 35K05, 65M80

Abstract

We present an active cloaking method for the parabolic heat (and mass or light diffusion) equation that can hide both objects and sources. By active we mean that it relies on designing monopole and dipole heat source distributions on the boundary of the region to be cloaked. The same technique can be used to make a source or an object look like a different one to an observer outside the cloaked region, from the perspective of thermal measurements. Our results assume a homogeneous isotropic bulk medium and require knowledge of the source to cloak or mimic, but are in most cases independent of the object to cloak., Comment: 29 pages,12 figures

Published

2020

33. Pulse dynamics of flexural waves in transformed plates

Author

Tang, Kun, Xu, Chenni, Guenneau, Sebastien, and Sebbah, Patrick

Subjects

Physics - Classical Physics

Abstract

Coordinate-transformation-inspired optical devices have been mostly examined in the continuous-wave regime: the performance of an invisibility cloak, which has been demonstrated for monochromatic excitation, %would inevitably is likely to deteriorate for short pulses. Here we investigate pulse dynamics of flexural waves propagating in transformed plates. We propose a practical realization of a waveshifter and a rotator for flexural waves based on the coordinate transformation method. Time-resolved measurements reveal how the waveshifter deviates a short pulse from its initial trajectory, with no reflection at the bend and no spatial and temporal distortion of the pulse. Extending our strategy to cylindrical coordinates, we design a wave rotator. We demonstrate experimentally how a pulsed plane wave is twisted inside the rotator, while its wavefront is recovered behind the rotator and the pulse shape is preserved, with no extra time delay. We propose the realization of the dynamical mirage effect, where an obstacle appears oriented in a deceptive direction.

Published

2020

34. The influence of structure geometry and material on seismic metamaterial performance

Author

Varma, T. Venkatesh, Ungureanu, Bogdan, Sarkar, Saikat, Craster, Richard, Guenneau, Sebastien, and Brule, Stephane

Subjects

Physics - Applied Physics

Abstract

Diverting, and controlling, elastic vibrations impacting upon infrastructure is a major challenge for seismic hazard mitigation, and for the reduction of machine noise and vehicle vibration in the urban environment. Seismic metamaterials (SMs), with their inherent ability to manipulate wave propagation, provide a key route for overcoming the technological hurdles involved in this challenge. Engineering the structure of the SM serves as a basis to tune and enhance its functionality, and inspired by split rings, swiss-rolls, notch-shaped and labyrinthine designs of elementary cells in electromagnetic and mechanical metamaterials, we investigate altering the structure geometries of SMs with the aim of creating large bandgaps \textcolor{black}{in a subwavelength regime}. We show that square stiff inclusions, perform better in comparison to circular ones, whilst keeping the same filling fraction. En route to enhancing the bandgap, we have also studied the performance of SMs with different constituent materials; we find that steel columns, as inclusions, show large bandgaps, however, the columns are too large for steel to be a feasible material in practical or financial terms. Non-reinforced concrete would be preferable for industry level scaling up of the technology because, concrete is cost-effective, easy to cast directly at the construction site and easy to provide arbitrary geometry of the structure. As a part of this study, we show that concrete columns can also be designed to exhibit bandgaps if we cast them within a soft soil coating surrounding the protected area for various civil structures like a bridge, building, oil pipelines etc.

Published

2020

35. Designing thermal energy harvesting devices with natural materials through optimized microstructures

Author

Ji, Qingxiang, Chen, Xueyan, Liang, Jun, Laude, Vincent, Guenneau, Sébastien, Fang, Guodong, and Kadic, Muamer

Subjects

Physics - Applied Physics, Condensed Matter - Materials Science, Physics - Computational Physics

Abstract

Metamaterial thermal energy devices obtained from transformation optics have recently attracted wide attention due to their vast potential in energy storage, thermal harvesting or heat manipulation. However, these devices usually require inhomogeneous and extreme material parameters which are difficult to realize in large-scale applications. Here, we demonstrate a general process to design thermal harvesting devices with available natural materials through optimized composite microstructures. We apply two-scale homogenization theory to obtain effective properties of the microstructures. Optimal Latin hypercube technique, combined with a genetic algorithm, is then implemented on the microstructures to achieve optimized design parameters. The optimized microstructures can accurately approximate the behavior of transformed materials. We design such devices and numerically characterize good thermal-energy harvesting performances. To validate the wide-range application of our approach, we illustrate other types of microstructures that mimic well the constitutive parameters. The approach we propose can be used to design novel thermal harvesting devices available with existing technology, and can also act as a beneficial vehicle to explore other transformation optics enabled designs., Comment: 9figures

Published

2020

36. Hybrid topological guiding mechanisms for photonic crystal fibers

Author

Makwana, Mehul P., Wiltshaw, Richard, Guenneau, Sébastien, and Craster, Richard V.

Subjects

Physics - Optics, Physics - Applied Physics

Abstract

We create hybrid topological-photonic localisation of light by introducing concepts from the field of topological matter to that of photonic crystal fiber arrays. S-polarized obliquely propagating electromagnetic waves are guided by hexagonal, and square, lattice topological systems along an array of infinitely conducting fibers. The theory utilises perfectly periodic arrays that, in frequency space, have gapped Dirac cones producing band gaps demarcated by pronounced valleys locally imbued with a nonzero local topological quantity. These broken symmetry-induced stop-bands allow for localised guidance of electromagnetic edge-waves along the crystal fiber axis. Finite element simulations, complemented by asymptotic techniques, demonstrate the effectiveness of the proposed designs for localising energy in finite arrays in a robust manner.

Published

2020

37. On the possibility of seismic rogue waves in very soft soils

Author

Brule, Stephane, Enoch, Stefan, and Guenneau, Sebastien

Subjects

Physics - Geophysics, Nonlinear Sciences - Pattern Formation and Solitons, Physics - Computational Physics, Physics - Fluid Dynamics

Abstract

Liquid wave studies have shown that under certain constructive interference conditions, an abnormal size wave could be generated at a specific point. This type of wave, described long ago in the literature, was named 'Draupner Wave' in 1995. It was the first rogue wave, more than ten meters high, to be detected by a measuring instrument, occurring at the Draupner platform in the North Sea off the coast of Norway. For very soft and thick soils in continental sedimentary basin, with high water content, low shear wave velocity and wave bouncing effects on the edges of the basin, one can question the theoretical existence of such a type of freak waves that may have come unnoticed amongst surface seismic waves. This short communication presents recent observations and the conditions and limits of the analogy between gravity and seismic waves., Comment: 13 pages, 7 figures

Published

2020

38. Scattering Cancellation Technique for Acoustic Spinning Objects

Author

Farhat, Mohamed, Guenneau, Sebastien, Alu, Andrea, and Wu, Ying

Subjects

Physics - Classical Physics

Abstract

The scattering cancellation technique (SCT) has proved to be an effective way to render static objects invisible to electromagnetic and acoustic waves. However, rotating cylindrical or spherical objects possess additional peculiar scattering features that cannot be cancelled by regular SCT-based cloaks. Here, a generalized SCT theory to cloak spinning objects, and hide them from static observers, based on rotating shells with different angular velocity is discussed. This concept is analytically and numerically demonstrated in the case of cylinders, showing that generalized SCT operates efficiently in making rotating objects appear static to an external observer. Our proposal extends the realm of SCT, and brings it one step closer to its practical realization that involves moving objects., Comment: 27 pages, 6 figures

Published

2020

39. Localising elastic edge waves via the topological rainbow effect

Author

Ungureanu, Bogdan, Makwana, Mehul P., Craster, Richard V., and Guenneau, Sebastien

Subjects

Physics - Applied Physics, Condensed Matter - Materials Science

Abstract

We combine two different fields, topological physics and graded metamaterials to design a topological metasurface to control and redirect elastic waves. We strategically design a two-dimensional crystalline perforated elastic plate, using a square lattice, %consisting of bore holes, that hosts symmetry-induced topological edge states. By concurrently allowing the elastic substrate to spatially vary in depth, we are able to convert the incident slow wave into a series of robust modes, with differing envelope modulations. This adiabatic transition localises the incoming energy into a concentrated region where it can then be damped or extracted. For larger transitions, different behaviour is observed; the incoming energy propagates along the interface before being partitioned into two disparate chiral beams. This "topological rainbow" effect leverages two main concepts, namely the quantum valley-Hall effect and the rainbow effect usually associated with electromagnetic metamaterials. The topological rainbow effect transcends specific physical systems, hence, the phenomena we describe can be transposed to other wave physics. Due to the directional tunability of the elastic energy by geometry our results have far-reaching implications for applications such as switches, filters and energy-harvesters.

Published

2020

40. Effective model for elastic waves propagating in a substrate supporting a dense array of plates/beams with flexural resonances

Author

Marigo, Jean-Jacques, Pham, Kim, Maurel, Agnès, and Guenneau, Sébastien

Subjects

Physics - Classical Physics, Physics - Computational Physics

Abstract

We consider the effect of an array of plates or beams over a semi-infinite elastic ground on the propagation of elastic waves hitting the interface. The plates/beams are slender bodies with flexural resonances at low frequencies able to perturb significantly the propagation of waves in the ground. An effective model is obtained using asymptotic analysis and homogenization techniques, which can be expressed in terms of the ground alone with effective dynamic (frequency-dependent) boundary conditions of the Robin's type. For an incident plane wave at oblique incidence, the displacement fields and the reflection coefficients are obtained in closed forms and their validity is inspected by comparison with direct numerics in a two-dimensional setting., Comment: 29 pages, 13 figures

Published

2020

41. Surface waves from flexural and compressional resonances of beams

Author

Marigo, Jean-Jacques, Pham, Kim, Maurel, Agnès, and Guenneau, Sébastien

Subjects

Physics - Computational Physics, Physics - Classical Physics, Physics - Geophysics

Abstract

We present a three-dimensional model describing the propagation of elastic waves in a soil substrate supporting an array of cylindrical beams experiencing flexural and compressional resonances. The resulting surface waves are of two types. In the sagittal plane, hybridized Rayleigh waves can propagate except within bandgaps resulting from a complex interplay between flexural and compressional resonances. We exhibit a wave decoupled from the hybridized Rayleigh wave which is the elastic analogue of electromagnetic spoof plasmon polaritons. This wave with displacements perpendicular to the sagittal plane is sensitive only to flexural resonances. Similar, yet quantitatively different, physics is demonstrated in a two-dimensional setting involving resonances of plates., Comment: 5 pages, 5 figures

Published

2020

42. The role of seismic metamaterials on soil dynamics

Author

Brule, Stephane and Guenneau, Sebastien

Subjects

Physics - Geophysics, Condensed Matter - Materials Science, Physics - Computational Physics

Abstract

Some properties of electromagnetic metamaterials have been translated, using some wave analogies, to surface seismic wave control in sedimentary soils structured at the meter scale. Two large scale experiments performed in 2012 near the French cities of Grenoble [Brule et al., PRL 112, 133901, 2014] and Lyon [Brule et al., Sci. Rep. 7, 18066, 2017] have confirmed the usefulness of this methodology and its potential influence on soil-structure interaction. We present here a new perspective on the in-situ experiment near Lyon, which unveils energy corridors in the seismic lens. We further introduce a concept of time-modulated seismic metamaterial underpined by an effective model based on Willis's equations. As a first application, we propose that ambient seismic noise time-modulates structured soils that can be viewed as moving media. In the same spirit, a design of an analogous seismic computer is proposed making use of ambient seismic noise. Seismic signals transmitted between remote seismic computers can help forming an Internet of Things. We further recall that ancient Roman theaters and forests of trees are examples of large scale structures that behave in a way similar to electromagnetic metamaterials: invisibility cloaks and rainbows, respectively. Seismic metamaterials can thus not only be implemented for shielding, lensing and cloaking of potentially deleterious Rayleigh waves, but they also have potential applications in energy harvesting and analogous computations using ambient seismic noise and this opens new vistas in seismic energy harvesting via natural or artificial soil structuring., Comment: 27 pages, 8 figures

Published

2019

43. Experimental observations of topologically guided water waves within non-hexagonal structures

Author

Makwana, Mehul P., Laforge, Nicolas, Craster, Richard V., Dupont, Guillaume, Guenneau, Sébastien, Laude, Vincent, and Kadic, Muamer

Subjects

Physics - Fluid Dynamics, Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

We investigate symmetry-protected topological water waves within a strategically engineered square lattice system. Thus far, symmetry-protected topological modes in hexagonal systems have primarily been studied in electromagnetism and acoustics, i.e. dispersionless media. Herein, we show experimentally how crucial geometrical properties of square structures allow for topological transport that is ordinarily forbidden within conventional hexagonal structures. We perform numerical simulations that take into account the inherent dispersion within water waves and devise a topological insulator that supports symmetry-protected transport along the domain walls. Our measurements, viewed with a high-speed camera under stroboscopic illumination, unambiguously demonstrate the valley-locked transport of water waves within a non-hexagonal structure. Due to the tunability of the energy's directionality by geometry, our results could be used for developing highly-efficient energy harvesters, filters and beam-splitters within dispersive media.

Published

2019

44. Mapping of elastic properties of twisting metamaterials onto micropolar continuum using static calculations

Author

Lemkalli, Brahim, Kadic, Muamer, El Badri, Youssef, Guenneau, Sébastien, Bouzid, Abdenbi, and Achaoui, Younes

Published

2023

45. Homogenization of quasiperiodic structures and two-scale cut-and-projection convergence

Author

Wellander, Niklas, Guenneau, Sébastien, and Cherkaev, Elena

Subjects

Mathematics - Analysis of PDEs, Condensed Matter - Materials Science, Physics - Optics

Abstract

Quasiperiodic arrangements of the constitutive materials in composites result in effective properties with very unusual electromagnetic and elastic properties. The paper discusses the cut-and-projection method that is used to characterize effective properties of quasiperiodic materials. Characterization of cut-and-projection convergence limits of partial differential operators is presented, and correctors are established. We provide the proofs of the results announced in (Wellander et al., 2018) and give further examples. Applications to problems of interest in physics include electrostatic, elastostatic and quasistatic magnetic cases., Comment: 28 pages, 2 figures

Published

2019

46. Cloaking in-plane elastic waves with swiss rolls

Author

Achaoui, Younes, Diatta, Andre, Kadic, Muamer, and Guenneau, Sebastien

Subjects

Physics - Computational Physics, Physics - Applied Physics

Abstract

We propose a design of cylindrical elastic cloak for coupled in-plane shear waves consisting of concentric layers of sub-wavelength resonant stress-free inclusions shaped as swiss-rolls. The scaling factor between inclusions' sizes is according to Pendry's transform. Unlike the hitherto known situations, the present geometric transform starts from a Willis medium and further assumes that displacement fields ${\bf u}$ in original medium and ${\bf u}'$ in transformed medium remain unaffected (${\bf u}'={\bf u}$), and this breaks the minor-symmetries of the rank-4 and rank-3 tensors in the Willis equation that describes the transformed effective medium. We achieve some cloaking for a shear polarized source at specific, resonant sub-wavelength, frequencies, when it is located near a clamped obstacle surrounded by the structured cloak. Such an effective medium allows for strong Willis coupling [Quan et al., Physical Review Letters {\bf 120}(25), 254301 (2018)], notwithstanding potential chiral elastic effects [Frenzel et al., Science {\bf 358}(6366), 1072 (2017)], and thus mitigates roles of Willis and Cosserat media in the achieved elastodynamic cloaking., Comment: 7 pages, 3 figures

Published

2019

47. Wavelet-based Edge Multiscale Finite Element Method for Helmholtz problems in perforated domains

Author

Fu, Shubin, Li, Guanglian, Craster, Richard, and Guenneau, Sebastien

Subjects

Mathematics - Numerical Analysis

Abstract

We introduce a new efficient algorithm for Helmholtz problems in perforated domains with the design of the scheme allowing for possibly large wavenumbers. Our method is based upon the Wavelet-based Edge Multiscale Finite Element Method (WEMsFEM) as proposed recently in [14]. For a regular coarse mesh with mesh size H, we establish O(H) convergence of this algorithm under the resolution assumption, and with the level parameter being sufficiently large. The performance of the algorithm is demonstrated by extensive 2-dimensional numerical tests including those motivated by photonic crystals.

Published

2019

48. Dynamic behavior of mechanical cloaks designed by direct lattice transformation

Author

Kadic, Muamer, Wegener, Martin, Nicolet, Andre, Zolla, Frederic, Guenneau, Sebastien, and Diatta, Andre

Subjects

Condensed Matter - Materials Science, Physics - Computational Physics

Abstract

Steering waves in elastic solids is more demanding than steering waves in electromagnetism or acoustics. As a result, designing material distributions which are the counterpart of optical invisibility cloaks in elasticity poses a major challenge. Waves of all polarizations should be guided around an obstacle to emerge on the downstream side as though no obstacle were there. Recently, we have introduced the direct-lattice-transformation approach. This simple and explicit construction procedure led to extremely good cloaking results in the static case. Here, we transfer this approach to the dynamic case, i.e., to elastic waves or phonons. We demonstrate broadband reduction of scattering, with best suppressions exceeding a factor of five when using cubic coordinate transformations instead of linear ones. To reliably and quantitatively test these cloaks efficiency, we use an effective-medium approach., Comment: 4 figures

Published

2019

49. Two-scale cut-and-projection convergence for quasiperiodic monotone operators

Author

Wellander, Niklas, Guenneau, Sébastien, and Cherkaev, Elena

Published

2023

50. Seismic wave shield using cubic arrays of split-ball resonators

Author

Ungureanu, Bogdan, Achaoui, Younes, Brule, Stephane, Enoch, Stefan, Craster, Richard, and Guenneau, Sebastien

Subjects

Physics - Classical Physics, Physics - Geophysics

Abstract

Metre size inertial resonators located in the ground have been theoretically shown to interact with a seismic wave (attenuation, band gaps) to enable protection of surface structures such as buildings. The challenge for Civil Engineering is to both reduce the size of these resonators and to increase their efficiency. Here we explore steel spheres, connected to a concrete bulk medium, either by a coating of rubber, or rubber and steel ligaments, or air and steel ligaments. We show that for a cubic lattice periodicity of 1 metre, we achieve stop bands in the frequency range 14 to 20 Hz; by splitting spheres in 2 and 8 pieces, we tune down the stop bands frequencies and further increase their bandwidth. We thus demonstrate we are able to provide a variety of inertial resonators with stop bands below 10 Hz i.e., in the frequency range of interest for earthquake engineering.

Published

2019