Your search keyword '"Arregui G"' showing total 8 results

1. Quantum Thermometry with Single Molecules in Nanoprobes

Author

Universidad de Sevilla. Departamento de Física de la Materia Condensada, Gobierno de España, Generalitat de Catalunya, Esteso Carrizo, Victoria, Duquennoy, R., Ng, R. C., Colautti, M., Lombardi, P., Arregui, G., Chávez Ángel, E., Sotomayor Torres, C. M., García, P. D, Hilke, M., Toninelli, C., Universidad de Sevilla. Departamento de Física de la Materia Condensada, Gobierno de España, Generalitat de Catalunya, Esteso Carrizo, Victoria, Duquennoy, R., Ng, R. C., Colautti, M., Lombardi, P., Arregui, G., Chávez Ángel, E., Sotomayor Torres, C. M., García, P. D, Hilke, M., and Toninelli, C.

Abstract

An understanding of heat transport is relevant to developing efficient strategies for thermal management in areas of study such as microelectronics, as well as for fundamental science purposes. However, the measurement of temperatures in nanostructured environments and in cryogenic conditions remains a challenging task, requiring both high sensitivity and noninvasive approaches. Here, we present a portable nanothermometer based on a molecular two-level quantum system that operates in the (3-20)-K temperature range, with temperatures and spatial resolutions on the order of millikelvins and micrometers, respectively. We validate the performance of this molecular thermometer by estimating the thermal conductivity of a nanopatterned silicon membrane, where we find a quadratic temperature dependence. In addition, we demonstrate two-dimensional temperature mapping via the simultaneous spectroscopy of multiple probes deposited onto such a suspended membrane. Overall, these results demonstrate the unique potential of the proposed molecular thermometer to explore thermal properties with submicron accuracy and unveil related phenomena manifested at cryogenic temperatures.

Published

2023

2. Ferromagnetic Resonance Assisted Optomechanical Magnetometer.

Author

Colombano, M. F., Arregui, G., Bonell, F., Capuj, N. E., Chavez-Angel, E., Pitanti, A., Valenzuela, S. O., Sotomayor-Torres, C. M., Navarro-Urrios, D., and Costache, M. V.

Subjects

*MAGNETOMETERS, *MAGNETIC fields, *SPIN waves, *FERROMAGNETIC materials, *SPIN excitations, *FERROMAGNETIC resonance, *MAGNETIC sensors

Abstract

The resonant enhancement of mechanical and optical interaction in optomechanical cavities enables their use as extremely sensitive displacement and force detectors. In this Letter, we demonstrate a hybrid magnetometer that exploits the coupling between the resonant excitation of spin waves in a ferromagnetic insulator and the resonant excitation of the breathing mechanical modes of a glass microsphere deposited on top. The interaction is mediated by magnetostriction in the ferromagnetic material and the consequent mechanical driving of the microsphere. The magnetometer response thus relies on the spectral overlap between the ferromagnetic resonance and the mechanical modes of the sphere, leading to a peak sensitivity of 850 pT Hz-1/2 at 206 MHz when the overlap is maximized. By externally tuning the ferromagnetic resonance frequency with a static magnetic field, we demonstrate sensitivity values at resonance around a few nT Hz-1/2 up to the gigahertz range. Our results show that our hybrid system can be used to build a high-speed sensor of oscillating magnetic fields. [ABSTRACT FROM AUTHOR]

Published

2020

3. Synchronization of Optomechanical Nanobeams by Mechanical Interaction.

Author

Colombano, M. F., Arregui, G., Capuj, N. E., Pitanti, A., Maire, J., Griol, A., Garrido, B., Martinez, A., Sotomayor-Torres, C. M., and Navarro-Urrios, D.

Subjects

*SYNCHRONIZATION, *NONLINEAR oscillators, *LASERS, *CRYSTALS, *NATURE

Abstract

The synchronization of coupled oscillators is a phenomenon found throughout nature. Mechanical oscillators are paradigmatic examples, but synchronizing their nanoscaled versions is challenging. We report synchronization of the mechanical dynamics of a pair of optomechanical crystal cavities that, in contrast to previous works performed in similar objects, are intercoupled with a mechanical link and support independent optical modes. In this regime they oscillate in antiphase, which is in agreement with the predictions of our numerical model that considers reactive coupling. We also show how to temporarily disable synchronization of the coupled system by actuating one of the cavities with a heating laser, so that both cavities oscillate independently. Our results can be upscaled to more than two cavities and pave the way towards realizing integrated networks of synchronized mechanical oscillators. [ABSTRACT FROM AUTHOR]

Published

2019

4. Anderson Photon-Phonon Colocalization in Certain Random Superlattices.

Author

Arregui, G., Lanzillotti-Kimura, N. D., Sotomayor-Torres, C. M., and García, P. D.

Subjects

*PHOTONS, *PHONONS, *GRAVITATIONAL waves

Abstract

Fundamental observations in physics ranging from gravitational wave detection to laser cooling of a nanomechanical oscillator into its quantum ground state rely on the interaction between the optical and the mechanical degrees of freedom. A key parameter to engineer this interaction is the spatial overlap between the two fields, optimized in carefully designed resonators on a case-by-case basis. Disorder is an alternative strategy to confine light and sound at the nanoscale. However, it lacks an a priori mechanism guaranteeing a high degree of colocalization due to the inherently complex nature of the underlying interference processes. Here, we propose a way to address this challenge by using GaAs/AlAs vertical distributed Bragg reflectors with embedded geometrical disorder. Because of a remarkable coincidence in the physical parameters governing light and motion propagation in these two materials, the equations for both longitudinal acoustic waves and normal-incidence light become practically equivalent for excitations of the same wavelength. This guarantees spatial overlap between the electromagnetic and displacement fields of specific photon-phonon pairs, leading to strong light-matter interaction. In particular, a statistical enhancement in the vacuum optomechanical coupling rate, go, is found, making this system a promising candidate to explore Anderson localization of high frequency (~20 GHz) phonons enabled by cavity optomechanics. The colocalization effect shown here unlocks the access to unexplored localization phenomena and the engineering of light-matter interactions mediated by Anderson-localized states. [ABSTRACT FROM AUTHOR]

Published

2019

5. Optomechanical coupling in the Anderson-localization regime.

Author

García, P. D., Bericat-Vadell, R., Arregui, G., Navarro-Urrios, D., Colombano, M., Alzina, F., and Sotomayor-Torres, C. M.

Subjects

*ELECTROMAGNETIC fields, *OPTOMECHANICS, *SEMICONDUCTORS

Abstract

Optomechanical crystals, purposely designed and fabricated semiconductor nanostructures, are used to enhance the coupling between the electromagnetic field and the mechanical vibrations of matter at the nanoscale. However, in real optomechanical crystals, imperfections open extra channels where the transfer of energy is lost, reducing the optomechanical coupling efficiency. Here, we quantify the role of disorder in a paradigmatic one-dimensional optomechanical crystal with full phononic and photonic band gaps. We show how disorder can be exploited as a resource to enhance the optomechanical coupling beyond engineered structures, thus providing a new tool set for optomechanics. [ABSTRACT FROM AUTHOR]

Published

2017

6. Optomechanical Generation of Coherent GHz Vibrations in a Phononic Waveguide.

Author

Madiot G, Ng RC, Arregui G, Florez O, Albrechtsen M, Stobbe S, García PD, and Sotomayor-Torres CM

Abstract

Nanophononics has the potential for information transfer, in an analogous manner to its photonic and electronic counterparts. The adoption of phononic systems has been limited, due to difficulties associated with the generation, manipulation, and detection of phonons, especially at GHz frequencies. Existing techniques often require piezoelectric materials with an external radiofrequency excitation that are not readily integrated into existing CMOS infrastructures, while nonpiezoelectric demonstrations have been inefficient. In this Letter, we explore the optomechanical generation of coherent phonons in a suspended 2D silicon phononic crystal cavity with a guided mode around 6.8 GHz. By incorporating an air-slot into this cavity, we turn the phononic waveguide into an optomechanical platform that exploits localized photonic modes resulting from inherent fabrication imperfections for the transduction of mechanics. Such a platform exhibits very fine control of phonons using light, and is capable of coherent self-sustained phonon generation around 6.8 GHz, operating at room temperature. The ability to generate high frequency coherent mechanical vibrations within such a simple 2D CMOS-compatible system could be a first step towards the development of sources in phononic circuitry and the coherent manipulation of other solid-state properties.

Published

2023

7. Cavity Optomechanics with Anderson-Localized Optical Modes.

Author

Arregui G, Ng RC, Albrechtsen M, Stobbe S, Sotomayor-Torres CM, and García PD

Abstract

Confining photons in cavities enhances the interaction between light and matter. In cavity optomechanics, this enables a wealth of phenomena ranging from optomechanically induced transparency to macroscopic objects cooled to their motional ground state. Previous work in cavity optomechanics employed devices where ubiquitous structural disorder played no role beyond perturbing resonance frequencies and quality factors. More generally, the interplay between disorder, which must be described by statistical physics, and optomechanical effects has thus far been unexplored. Here, we demonstrate how sidewall roughness in air-slot photonic-crystal waveguides can induce sufficiently strong backscattering of slot-guided light to create Anderson-localized modes with quality factors as high as half a million and mode volumes estimated to be below the diffraction limit. We observe how the interaction between these disorder-induced optical modes and in-plane mechanical modes of the slotted membrane is governed by a distribution of coupling rates, which can exceed g_{o}/2π∼200  kHz, leading to mechanical amplification up to self sustained oscillations via optomechanical backaction. Our Letter constitutes the first steps towards understanding optomechanics in the multiple-scattering regime and opens new perspectives for exploring complex systems with a multitude of mutually coupled degrees of freedom.

Published

2023

8. Quantifying the Robustness of Topological Slow Light.

Author

Arregui G, Gomis-Bresco J, Sotomayor-Torres CM, and Garcia PD

Abstract

The backscattering mean free path ξ, the average ballistic propagation length along a waveguide, quantifies the resistance of slow light against unwanted imperfections in the critical dimensions of the nanostructure. This figure of merit determines the crossover between acceptable slow-light transmission affected by minimal scattering losses and a strong backscattering-induced destructive interference when the waveguide length L exceeds ξ. Here, we calculate the backscattering mean free path for a topological photonic waveguide for a specific and determined amount of disorder and, equally relevant, for a fixed value of the group index n_{g} which is the slowdown factor of the group velocity with respect to the speed of light in vacuum. These two figures of merit, ξ and n_{g}, should be taken into account when quantifying the robustness of topological and conventional (nontopological) slow-light transport at the nanoscale. Otherwise, any claim on a better performance of topological guided light over a conventional one is not justified.

Published

2021