Your search keyword '"Golat, Sebastian"' showing total 3 results

1. Chiral longitudinal forces in dielectric photonic waveguides.

Author

Martínez-Romeu, Josep, Diez, Iago, Golat, Sebastian, Rodríguez-Fortuño, Francisco J., and Martínez, Alejandro

Subjects

*ENANTIOSELECTIVE catalysis, *DIELECTRICS, *WAVEGUIDES, *PHARMACOLOGY, *ENANTIOMERS

Abstract

Chiral optical forces exhibit opposite signs for the two enantiomeric versions of a chiral molecule or particle. If large enough, these forces might be able to separate enantiomers all-optically, which would find numerous applications in different fields, from pharmacology to chemistry. Longitudinal chiral forces are especially promising for tackling the challenging scenario of separating particles of realistically small chiralities. In this work, we study the longitudinal chiral forces arising in dielectric integrated waveguides when the quasi-TE and quasi-TM modes are combined, for enabling the separation of absorbing and non-absorbing chiral particles. We show that chiral gradient forces dominate in the scenario of beating of non-degenerate TE and TM modes when considering non-absorbing particles. For absorbing particles, the superposition of degenerate TE and TM modes can lead to radiation pressure chiral forces that are kept along the whole waveguide length. We accompany the calculations of the forces with particle tracking simulations for one specific radius and chirality parameter and show that longitudinal forces can separate chiral nanoparticles suspended in water even for relatively low values of the particle chirality. [ABSTRACT FROM AUTHOR]

Published

2024

2. Geodesic noise and gravitational wave observations by pulsar timing arrays.

Author

Golat, Sebastian and Contaldi, Carlo R.

Subjects

*GEODESICS, *DISTRIBUTION of stars, *STELLAR mass, *SOLAR system, *NOISE

Abstract

Signals from millisecond pulsars travel to us on geodesics along the line-of-sight that are affected by the space–time metric. The exact path-geometry and redshifting along the geodesics determine the observed Time-of-Arrival (ToA) of the pulses. The metric is determined by the distribution of dark matter, gas, and stars in the galaxy and, in the final stages of travel, by the distribution of solar system bodies. The inhomogeneous distribution of stellar masses can have a small but significant statistical effect on the ToAs through the perturbation of geodesics. This will result in additional noise in ToA observations that may affect Pulsar Timing Array (PTA) constraints on gravitational waves at very low frequencies. We employ a simple model for the stellar distribution in our galaxy to estimate the scale of both static and dynamic sources of what we term generically "geodesic noise". We find that geodesic noise has a standard deviation of O (10) ns for typical lines-of-sight. This suggests geodesic noise is relevant for estimates of PTA sensitivity and may limit future efforts for detection of gravitational waves by PTAs. [ABSTRACT FROM AUTHOR]

Published

2021

3. Evanescent gravitational waves.

Author

Golat, Sebastian, Lim, Eugene A., and Rodríguez-Fortuño, Francisco J.

Subjects

*ANATOMICAL planes, *ANGULAR momentum (Mechanics), *ACOUSTICS, *OPTICS, *GRAVITY, *GRAVITATIONAL waves, *EINSTEIN field equations

Abstract

We describe the properties of evanescent gravitational waves (EGWs)--wave solutions of Einstein equations which decay exponentially in some direction while propagating in another. Evanescent waves are well known in acoustics and optics and have recently received much attention due to their extraordinary properties such as their transverse spin and spin-momentum locking. We show that EGWs possess similarly remarkable properties, carrying transverse spin angular momenta and driving freely falling test masses along in elliptical trajectories. Hence, test masses on a plane transverse to the direction of propagation exhibit correlated vector and scalarlike deformation--correlations which can be used to distinguish it from modified gravity. We demonstrate that EGWs are present and dominant in the vicinity of subwavelength sources such as orbiting binaries. [ABSTRACT FROM AUTHOR]

Published

2020