Your search keyword '"Goïcoechea, Antton"' showing total 7 results

1. Detecting and Focusing on a Nonlinear Target in a Complex Medium

Author

Goïcoechea, Antton, Hüpfl, Jakob, Rotter, Stefan, Sarrazin, François, and Davy, Matthieu

Subjects

Physics - Applied Physics, Physics - Optics

Abstract

Wavefront shaping techniques allow waves to be focused on a diffraction-limited target deep inside disordered media. To identify the target position, a guidestar is required that typically emits a frequency-shifted signal. Here we present a noninvasive matrix approach operating at a single frequency only, based on the variation of the field scattered by a nonlinear target illuminated at two incident powers. The local perturbation induced by the nonlinearity serves as a guide for identifying optimal incident wavefronts. We demonstrate maximal focusing on electronic devices embedded in chaotic microwave cavities and extend our approach to temporal signals. Finally, we exploit the programmability offered by reconfigurable smart surfaces to enhance the intensity delivered to a nonlinear target. Our results pave the way for deep imaging protocols that use any type of nonlinearity as feedback, requiring only the measurement of a monochromatic scattering matrix.

Published

2024

2. Reflection Measurement of the Scattering Mean Free Path at the Onset of Multiple Scattering

Author

Goïcoechea, Antton, Brütt, Cécile, Ber, Arthur Le, Bureau, Flavien, Lambert, William, Prada, Claire, Derode, Arnaud, and Aubry, Alexandre

Subjects

Physics - Medical Physics, Condensed Matter - Disordered Systems and Neural Networks, Physics - Applied Physics

Abstract

Multiple scattering of waves presents challenges for imaging complex media but offers potential for their characterization. Its onset is actually governed by the scattering mean free path $\ell_s$ that provides crucial information on the medium micro-architecture. Here, we introduce a reflection matrix method designed to estimate this parameter from the time decay of the single scattering rate. Our method is first validated by an ultrasound experiment on a tissue-mimicking phantom before being applied in-vivo to a human liver. This study opens important perspectives for quantitative imaging of heterogeneous media with waves, whether it be for non-destructive testing, biomedical or geophysical applications., Comment: 29 pages, 7 figures

Published

2024

3. Anisotropy of localized states in an anisotropic disordered medium

Author

Goïcoechea, Antton, Page, John H., and Skipetrov, Sergey E.

Subjects

Condensed Matter - Disordered Systems and Neural Networks

Abstract

We study Anderson localization of a scalar wave in an ensemble of resonant point scatterers embedded in an anisotropic background medium. For uniaxial anisotropy of moderate strength, the mobility edges and the critical exponent of the localization transition are found to be unaffected by the anisotropy provided that the determinant of the anisotropy tensor is kept equal to one upon introducing the anisotropy. Localized modes have anisotropic spatial shapes although their anisotropy is weaker than the one expected from purely geometric considerations. The modes with the longest lifetimes are found to be the most anisotropic and their anisotropy increases with the size of the disordered medium., Comment: 11 pages, 4 figures

Published

2021

4. Suppression of transport anisotropy at the Anderson localization transition in three-dimensional anisotropic media

Author

Goïcoechea, Antton, Skipetrov, Sergey E., and Page, John H.

Subjects

Condensed Matter - Disordered Systems and Neural Networks

Abstract

We study the transport of classical waves through three-dimensional (3D) anisotropic media close to the Anderson localization transition. Time-, frequency-, and position-resolved ultrasonic measurements are performed on anisotropic slab-shaped mesoglass samples to probe the dynamics and the anisotropy of the multiple scattering halo, and hence to investigate the influence of disorder on the nature of wave transport and its anisotropy. These experiments allow us to address conflicting theoretical predictions that have been made about whether or not the transport anisotropy is affected by the interference effects that lead to Anderson localization. We find that the transport anisotropy is significantly reduced as the mobility edge is approached---a behavior similar to the one predicted recently for matter waves in infinite anisotropic 3D media., Comment: 5 pages, 3 figures

Published

2020

5. Anisotropy of localized states in an anisotropic disordered medium

Author

Goïcoechea, Antton, primary, Page, John H., additional, and Skipetrov, Sergey E., additional

Published

2021

6. Anderson localization of ultrasound in disordered anisotropic media

Author

Rotter, Stefan (Vienna University of Technology) Burgess, Jacob (Physics and Astronomy) Sirker, Jesko (Physics and Astronomy) Bridges, Gregory (Electrical and Computer Engineering), Page, John H. (Physics and Astronomy), Goïcoechea, Antton, Rotter, Stefan (Vienna University of Technology) Burgess, Jacob (Physics and Astronomy) Sirker, Jesko (Physics and Astronomy) Bridges, Gregory (Electrical and Computer Engineering), Page, John H. (Physics and Astronomy), and Goïcoechea, Antton

Abstract

Wave transport in disordered anisotropic media is investigated experimentally and theoretically. Multiple scattering theory is reviewed, with a focus on the self-consistent theory of localization (SCT). To treat anisotropy, a new version of this theory is adapted to classical waves and extended to finite media. By obtaining analytical results, the two versions of the SCT have been compared in the infinite medium case and found to be in good agreement. Experimentally, the transport is studied via ultrasonic techniques on samples made of brazed elongated aluminium particles oriented in a certain direction. In the diffusive regime, the effect of the anisotropy is to make directions of propagation inside the sample inequivalent. Instead of a single diffusion coefficient, components of a diffusion tensor can be measured in the anisotropic case. Experimental results show good agreement with diffusion theory for two different orientations of the particles. The frequency-independence of the transport anisotropy is demonstrated experimentally for the first time. Using a novel technique to increase the scattering inside the samples, transport regimes for which the diffusion approximation breaks down are reached. In particular, the effect of the anisotropy on the Anderson localization regime is studied. Using transverse confinement experiments, the first experimental observation of the reduction of the transport anisotropy close to the mobility edge is reported for both orientations of the anisotropy. The samples made of these irregular elongated particles also display a slow approach to the localization regime, motivating further experimental work. A theoretical framework based on random matrix theory is used to study the effects of anisotropy on the transport of scalar waves. Introducing correlations such as grouping scatterers by pairs or surrounding scatterers by a spherical exclusion volume results in exotic behaviour compared to the independent scatterers case. The pair

Published

2020

7. Suppression of transport anisotropy at the Anderson localization transition in three-dimensional anisotropic media

Author

Goïcoechea, Antton, primary, Skipetrov, Sergey E., additional, and Page, John H., additional

Published

2020