Your search keyword '"Tudor Cristea-Platon"' showing total 5 results

1. A hydrodynamic analog of Friedel oscillations

Author

Pedro Saenz, Tudor Cristea-Platon, and John W. M. Bush

Subjects

Physics, Friedel oscillations, Multidisciplinary, Drop (liquid), SciAdv r-articles, Probability density function, Electron, Condensed Matter::Mesoscopic Systems and Quantum Hall Effect, 01 natural sciences, 010305 fluids & plasmas, Open quantum system, Classical mechanics, Condensed Matter::Superconductivity, 0103 physical sciences, Wave field, Condensed Matter::Strongly Correlated Electrons, 010306 general physics, Quantum, Research Articles, Research Article

Abstract

We report a new classical analog of electron scattering from an impurity on a metal surface., We present a macroscopic analog of an open quantum system, achieved with a classical pilot-wave system. Friedel oscillations are the angstrom-scale statistical signature of an impurity on a metal surface, concentric circular modulations in the probability density function of the surrounding electron sea. We consider a millimetric drop, propelled by its own wave field along the surface of a vibrating liquid bath, interacting with a submerged circular well. An ensemble of drop trajectories displays a statistical signature in the vicinity of the well that is strikingly similar to Friedel oscillations. The droplet trajectories reveal the dynamical roots of the emergent statistics. Our study elucidates a new mechanism for emergent quantum-like statistics in pilot-wave hydrodynamics and so suggests new directions for the nascent field of hydrodynamic quantum analogs.

Published

2020

2. Statistical projection effects in a hydrodynamic pilot-wave system

Author

Tudor Cristea-Platon, Pedro Saenz, and John W. M. Bush

Subjects

Physics, Pilot wave, Field (physics), General Physics and Astronomy, Electron, 01 natural sciences, Projection (linear algebra), 010305 fluids & plasmas, Quantum realm, Quantum mirage, Classical mechanics, Excited state, 0103 physical sciences, 010306 general physics, Quantum

Abstract

Millimetric liquid droplets can walk across the surface of a vibrating fluid bath, self-propelled through a resonant interaction with their own guiding or ‘pilot’ wave fields. These walking droplets, or ‘walkers’, exhibit several features previously thought to be peculiar to the microscopic, quantum realm. In particular, walkers confined to circular corrals manifest a wave-like statistical behaviour reminiscent of that of electrons in quantum corrals. Here we demonstrate that localized topological inhomogeneities in an elliptical corral may lead to resonant projection effects in the walker’s statistics similar to those reported in quantum corrals. Specifically, we show that a submerged circular well may drive the walker to excite specific eigenmodes in the bath that result in drastic changes in the particle’s statistical behaviour. The well tends to attract the walker, leading to a local peak in the walker’s position histogram. By placing the well at one of the foci, a mode with maxima near the foci is preferentially excited, leading to a projection effect in the walker’s position histogram towards the empty focus, an effect strongly reminiscent of the quantum mirage. Finally, we demonstrate that the mean pilot-wave field has the same form as the histogram describing the walker’s statistics. Droplets moving on the surface of a vibrating fluid bath mimic the behaviour of electrons in quantum corrals. Introducing submerged features in the bath can even drive the droplets to excite modes that induce effects reminiscent of quantum mirages.

Published

2017

3. Walking droplets in a circular corral: Quantisation and chaos

Author

Tudor Cristea-Platon, Pedro Saenz, and John W. M. Bush

Subjects

Physics, Angular momentum, Applied Mathematics, General Physics and Astronomy, Statistical and Nonlinear Physics, Electron, Radius, Simple harmonic motion, 01 natural sciences, 010305 fluids & plasmas, Quantum realm, Acceleration, Classical mechanics, 0103 physical sciences, Two-phase flow, 010306 general physics, Quantum, Mathematical Physics

Abstract

A millimetric liquid droplet may walk across the surface of a vibrating liquid bath through a resonant interaction with its self-generated wavefield. Such walking droplets, or “walkers,” have attracted considerable recent interest because they exhibit certain features previously believed to be exclusive to the microscopic, quantum realm. In particular, the intricate motion of a walker confined to a closed geometry is known to give rise to a coherent wave-like statistical behavior similar to that of electrons confined to quantum corrals. Here, we examine experimentally the dynamics of a walker inside a circular corral. We first illustrate the emergence of a variety of stable dynamical states for relatively low vibrational accelerations, which lead to a double quantisation in angular momentum and orbital radius. We then characterise the system’s transition to chaos for increasing vibrational acceleration and illustrate the resulting breakdown of the double quantisation. Finally, we discuss the similarities and differences between the dynamics and statistics of a walker inside a circular corral and that of a walker subject to a simple harmonic potential.A millimetric liquid droplet may walk across the surface of a vibrating liquid bath through a resonant interaction with its self-generated wavefield. Such walking droplets, or “walkers,” have attracted considerable recent interest because they exhibit certain features previously believed to be exclusive to the microscopic, quantum realm. In particular, the intricate motion of a walker confined to a closed geometry is known to give rise to a coherent wave-like statistical behavior similar to that of electrons confined to quantum corrals. Here, we examine experimentally the dynamics of a walker inside a circular corral. We first illustrate the emergence of a variety of stable dynamical states for relatively low vibrational accelerations, which lead to a double quantisation in angular momentum and orbital radius. We then characterise the system’s transition to chaos for increasing vibrational acceleration and illustrate the resulting breakdown of the double quantisation. Finally, we discuss the similarities ...

Published

2018

4. Spin lattices of walking droplets

Author

Alexis Goujon, John W. M. Bush, Jörn Dunkel, Pedro Saenz, Tudor Cristea-Platon, Giuseppe Pucci, Massachusetts Institute of Technology. Department of Mathematics, Massachusetts Institute of Technology. Department of Physics, Saenz Hervias, Pedro Javier, Pucci, Giuseppe, Goujon, Alexis Marie Fr, Cristea-Platon, Tudor, Dunkel, Jorn, and Bush, John W. M.

Subjects

Fluid Flow and Transfer Processes, Physics, Work (thermodynamics), Classical mechanics, Modeling and Simulation, 0103 physical sciences, Computational Mechanics, Fluid motion, 010306 general physics, 01 natural sciences, 010305 fluids & plasmas, Spin-½

Abstract

This paper is associated with a video winner of a 2017 APS/DFD Gallery of Fluid Motion Award for work presented at the DFD Gallery of Fluid Motion. The original video is available from the Gallery of Fluid Motion, https://doi.org/10.1103/APS.DFD.2017.GFM.V0018, National Science Foundation (U.S.) (Grant No. CMMI-1333242), National Science Foundation (U.S.) (Grant No. DMS-1614043), National Science Foundation (U.S.) (Grant No. CMMI-1727565)

Published

2018

5. Video: Spin lattices of walking droplets

Author

Tudor Cristea-Platon, John W. M. Bush, Pucci Giuseppe, Jörn Dunkel, Pedro Saenz, and Alexis Goujon

Subjects

Physics, Optics, Condensed matter physics, business.industry, business, Spin-½

Published

2017