Radiação Hawking de um buraco negro acústico não-comutativo.

LUNA, Gabriela Coutinho.

06 November 2018

Submitted by Emanuel Varela Cardoso (emanuel.varela@ufcg.edu.br) on 2018-11-06T20:40:37Z No. of bitstreams: 1 GABRIELA COUTINHO LUNA – DISSERTAÇÃO (PPGFísica) 2016.pdf: 715387 bytes, checksum: 874a57d0f89fb17ac576dd091e90bb48 (MD5) / Made available in DSpace on 2018-11-06T20:40:37Z (GMT). No. of bitstreams: 1 GABRIELA COUTINHO LUNA – DISSERTAÇÃO (PPGFísica) 2016.pdf: 715387 bytes, checksum: 874a57d0f89fb17ac576dd091e90bb48 (MD5) Previous issue date: 2016-02 / O estudo do buraco negro acústico, ou análogo acústico, se assemelha ao gravitacional da seguinte forma: verifi ca-se o fenômeno da radiação Hawking, apresença de um horizonte de eventos, a possibilidade de se calcular a sua temperatura, também chamada de temperatura Hawking, e obtêm-se uma métrica que descreve a geometria do buraco negro. Inserimos na métrica acústica a teoria não-comutativa, a fim de vericar as correções que resultam desta teoria. Neste trabalho, consideramos o princípio da incerteza generalizado, no formalismo de tunelamento via método de Hamilton-Jacobi, para determinar a temperatura Hawking e a entropia quântica corrigida para buracos negros acústicos não comutativo sem 2+1 dimensões. Em nossos resultados obtemos uma entropia de área, comum termo de correção logarítmica em ordem dominante um termo, em ordem menor, proporcional à temperatura de radiação associada com os buracos negros acústicos comutativos e um termo extra que depende de uma carga conservada. Assim, como no caso gravitacional, não há necessidade de apresentar o corte ultravioleta e as divergências são eliminadas. / Acoustic black hole study resembles the gravitational black hole as follows: we verify Hawking radiation phenomenon the presence of an event horizon, the possibility to calculate its temperature, also known as Hawking temperature, and we obtain a metric that describes the black hole geometry. We insert in the acoustic metric theory the non commutative theory in order to verify the corrections that result from this theory. In this study, we consider the generalized uncertainty principle in tunneling formalism by Hamilton-Jacobi method to determine Hawking temperature and quantum entropy corrected for non commutative acoustic black holes in 2+1 dimensions. In our results, we obtain an entropy are a with a termoflogarith mic correction in ruling order a termina smaller order, proportional to the radiation temperature associated with the commutative acoustic black holes and an extra term that depends on a conserved charge. Thus as in the gravitational case, there is noneed to present the ultraviolet cut-off and differences are eliminated.

Física

Radiação Hawking

Buraco negro acústico

Princípio da incerteza

Hawking Radiation

Acoustic black hole

Principle of uncertainty

Nonlocal Acoustic Black Hole Metastructures: Achieving Ultralow Frequency and Broadband Vibration Attenuation

Siddharth Nair (7887968)

21 November 2019

<div>The development of novel passive techniques for vibration attenuation and control of broadband energy propagation through structural systems have been a major challenge in various complex engineering applications. These passive attenuation and control methodologies are necessary for the efficient performance of advanced lightweight aerospace and mechanical systems operating under extreme working conditions.</div><div><br></div><div>Acoustic Black Holes (ABH) have rapidly emerged as an effective approach to either dissipate or harvest mechanical energy in vibrating thin-walled structures. The characteristic dimension of an ABH, typically its diameter, is strictly connected to the occurrence of a cut-on frequency value below which the ABH is ineffective in absorbing the incoming wave. From a general perspective, lower the cut-on frequency, larger the ABH diameter needed to absorb the incoming wave. Design and manufacturing constraints of the host structure impose stringent limitations on the maximum ABH diameter and hence, limiting the lowest achievable cut-on frequency. The combination of these factors typically result in the poor energy extraction performance at low frequencies.</div><div><br></div><div>This thesis proposes the concept and explores the performance of an intentional nonlocal design for periodic grids of ABHs embedded in thin plates (referred to as ABH metastructures). The nonlocal design is conceived with the twofold objective of lowering the cut-on frequency of the ABH grids and extending the operating frequency range so as to achieve broadband performance. Different nonlocal designs are presented and their dynamic performances are investigated using numerical models. As opposed to the traditional material nonlocality, this thesis introduces nonlocal effects using an intentionally tailored geometric approach. A secondary layer is connected to the load-bearing ABH metastructure base, whose dynamic properties are sought to be controlled.</div><div><br></div><div>A semi-analytical model is also presented in order to characterize the role of nonlocality on the dispersion behavior and its effect on the broadband dynamic response. In linear elasticity, material nonlocality is mathematically represented by a spatially varying attenuation function. As the nonlocal model developed in this thesis follows geometric nonlocality approach, the required nonlocal attenuation factor is found to have a spatial as well as a temporal dependence. The analytical nonlocal constitutive relations in conjunction with the numerically obtained stress-strain parameters are used to identify the dynamic attenuation factor for the nonlocal ABH metastructure. The results provide substantial theoretical and numerical evidence of the potential of engineered nonlocal ABH design as an efficient ultra-low frequency passive attenuation technique for lightweight structures.</div>

Aerospace Engineering

Mechanical Engineering

Aerospace Structures

Structural Engineering

Nonlocality

Acoustic black hole

Metastructure

ultralow frequency range

Vibration damping

Propagation d'ondes dans un guide inhomogène : application à la cochlée / Wave propagation in an inhomogeneous waveguide : application to the mammalian cochlea

Foucaud, Simon

19 October 2012

Dans la cochlée, la réponse couplée de sa structure et de son fluide interne peut être représentée sous la forme d’une onde dont les caractéristiques varient en fonction de la position longitudinale. La méthode asymptotique Wentzel-Kramers-Brillouin est adaptée à la modélisation de ce type d’onde. Dans un premier temps, cette méthode est reprise. Un modèle numérique est également développé et les résultats des deux méthodes sont comparés. Dans un deuxième temps, la métohde Wentzel-Kramers-Brillouin est améliorée afin de prendre en compte le couplage entre plusieurs ondes. Le couplage d’un mode propagatif avec des modes évanescents est réalisé et validé. Dans la cochlée, la stimulation des cellules cillées résulte d’un mouvement de cisaillement de la membrane tectoriale et de flexion de la membrane basilaire. Le couplage entre ces deux modes de déformation est encore peu connu et offre une perspective intéressante. Dans un troisième temps, une nouvelle méthode couplant la méthode Wentzel-Kramesr Brillouin et une méthode numérique est développée et validée afin de déterminer des modes transverses de propagation. Cette méthode est appliquée à la mécanique cochléaire et un mode de flexion de la membrane basilaire et un mode relatif à un mouvement de cisaillement de la membrane tectoriale sont déterminés. Enfin, une expérience inspirée des cochlées artificielles est conçue et réalisée. La propagation d’ondes est observée et la tonotopie est mesurée et comparée aux modèles. Afin de limiter la réflexion des ondes et de faciliter la mesure, une combinaison originale du trou noir acoustique avec une lame de largeur variable est utilisée. / The cochlea is the organ of hearing for humans and mammals. It is often modelled as an inhomogeneous waveguide. A travelling wave propagates along the fluid structure coupled waveguide. The mechanical impedance of the structure is varying and provides a frequency place relation. The asymptotic method Wentzel-Kramers-Brillouin allows to solve for the basilar membrane vibration. The evanescents modes are taken into account to provide a better representation compared to the numerical models. As a second step, the finite elements method is used to solve for the transversal modes while the WKB Approximation deals with the longitudinal propagation. The first flexural mode of the basilar membrane is shown. The second propagative mode reveals a shearing motion of the tectorial membrane which can help stimulating the hair cells. An over-size artificial cochlea is designed and built. Thanks to an acoustic black hole, used as a anechoic end, travelling waves are observed on this device. Reflected waves are attenuated and the interferences with incident waves reduced. Mode coupling could be applied not only to evanescent modes but also to propagatives ones. Perspectives for the adaptation of the WKB method to fluid structure inhomogeneous waveguides, and particularly to the immersed acoustic black hole, seem to be very promising.

Cochlée

Guide d’onde inhomogène

Dispersion

Amortissement

Couplage de modes

Trou noir acoustique

Cochlée artificielle

Tonotopie

Cochlea

Inhomogeneous waveguide

Dispersion

Mode coupling

Acoustic Black Hole

Artificial Cochlea

Tonotopy

620.1

Controlling flexural waves using subwavelength perfect absorbers : application to Acoustic Black Holes / Contrôle des ondes de flexion au moyen d’absorbeurs parfaits sub-longueur d’onde : application au trou noir acoustique

Leng, Julien

05 November 2019

Le contrôle des vibrations à basse fréquence adapté aux structures légères est un défi scientifique ettechnologique en raison de contraintes économiques et écologiques de plus en plus strictes. De récentes études enacoustique ont portées sur l’absorption totale d’ondes basses fréquences à l’aide d’absorbeurs parfaits sublongueursd’onde. Ces métamatériaux sont obtenus en exploitant la condition de couplage critique. Unegénéralisation de cette méthode pour le domaine élastodynamique serait d’un grand intérêt pour répondre auxexigences du contrôle des vibrations de structures légères à basse fréquence.Cette thèse vise à adapter le problème d’absorption parfaite des ondes de flexion dans des systèmes 1D et 2D avecdes résonateurs locaux en utilisant la condition de couplage critique. Une étude préliminaire sur des systèmes 1D àgéométries simples sont d’abord proposée. Celle-ci propose une méthode de conception de résonateurs simplespour une absorption efficace des ondes de flexion. Une complexification du système 1D est ensuite considérée avecl’étude du couplage critique de Trou Noir Acoustique (TNA) 1D. Ceci a motivé l’interprétation de l’effet TNA à l’aidedu concept de couplage critique afin de présenter des outils clés à de futures procédures d’optimisation pour ce typede terminaisons. La condition de couplage critique est ensuite étendue aux systèmes 2D. L’absorption parfaite parle premier mode axisymétrique d’un résonateur circulaire inséré dans une plaque mince infinie est analysée. Ladiffusion multiple par une ligne de résonateurs circulaires insérés dans une plaque mince 2D infinie ou semi-infinie,appelée métaplaque, est aussi considérée dans l’optique de se rapprocher d’une application industrielle. A traverscette thèse, des modèles analytiques, des simulations numériques et des expériences sont présentés pour valider lecomportement physique des systèmes présentés. / The vibration control adapted to light structures is a scientific and technological challenge due toincreasingly stringent economic and ecological standards. Meanwhile, recent studies in audible acoustics havefocused on broadband wave absorption at low frequencies by means of subwavelength perfect absorbers. Suchmetamaterials can totally absorb the energy of an incident wave. The generalisation of this method for applicationsin elastodynamics could be of great interest for the vibration control of light structures.This thesis aims at adapting the perfect absorption problem for flexural waves in 1D and 2D systems with localresonators using the critical coupling condition. A study of 1D systems with simple geometries is first proposed. Thisprovides methods to design simple resonators for an effective absorption of flexural waves. The 1D systems thenbecome more complex by studying the critical coupling of 1D Acoustic Black Holes (ABH). The ABH effect is theninterpreted using the concept of critical coupling, and key features for future optimisation procedures of ABHs arepresented. The critical coupling condition is then extended to 2D systems. The perfect absorption by the firstaxisymmetric mode of a circular resonator inserted in a thin plate is analysed. Multiple scattering by an array ofcircular resonators inserted in an infinite or semi-infinite 2D thin plate, called metaplate, is also considered to getclose to practical applications. Through this thesis, analytical models, numerical simulations and experiments areshown to validate the physical behaviour of the systems presented.

Contrôle passif d'onde

Onde de flexion

Métamatériau

Structure localement résonante

Absorption parfaite

Couplage critique

Trou Noir Acoustique

Passive wave control

Flexural waves

Metamaterial

Locally resonant structure

Perfect absorption

Critical coupling

Acoustic Black Hole

620.3