Fractal particle trajectories in capillary waves: Imprint of wavelength

Adam E. Hansen; Elsebeth Schröder; Preben Alstrøm; Jacob Sparre Andersen; Mogens T. Levinsen

doi:10.1103/PhysRevLett.79.1845

Fractal particle trajectories in capillary waves: Imprint of wavelength

Adam E. Hansen, Elsebeth Schröder, Preben Alstrøm, Jacob Sparre Andersen, Mogens T. Levinsen

24 Citations (Scopus)

Abstract

We examine particle trajectories in capillary waves formed on a water surface subject to vertical vibrations. We focus on the role of a distinct length scale present in our experiment, namely, the wavelength λ of the surface waves. We observe non-Brownian particle trajectories with a fractal dimension D different from the random walk value D = 2. A crossover is observed from one anomalous behavior at length scales below λ, to another at larger length scales. Data collapse is shown to be feasible, and scaling functions characterizing the crossover are identified. Our results are compared to those obtained from observations of drifters in the upper ocean. The distinct length scale λ allows us to divide the particle trajectories into flights and traps. The distribution of flight times shows a power-law behavior with an exponent between 2.3 and 3.

Original language	English
Journal	Physical Review Letters
Volume	79
Issue number	10
Pages (from-to)	1845-1848
Number of pages	4
ISSN	0031-9007
DOIs	https://doi.org/10.1103/PhysRevLett.79.1845
Publication status	Published - 1997
Externally published	Yes

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10.1103/PhysRevLett.79.1845

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title = "Fractal particle trajectories in capillary waves: Imprint of wavelength",

abstract = "We examine particle trajectories in capillary waves formed on a water surface subject to vertical vibrations. We focus on the role of a distinct length scale present in our experiment, namely, the wavelength λ of the surface waves. We observe non-Brownian particle trajectories with a fractal dimension D different from the random walk value D = 2. A crossover is observed from one anomalous behavior at length scales below λ, to another at larger length scales. Data collapse is shown to be feasible, and scaling functions characterizing the crossover are identified. Our results are compared to those obtained from observations of drifters in the upper ocean. The distinct length scale λ allows us to divide the particle trajectories into flights and traps. The distribution of flight times shows a power-law behavior with an exponent between 2.3 and 3.",

author = "Hansen, \{Adam E.\} and Elsebeth Schr{\"o}der and Preben Alstr{\o}m and Andersen, \{Jacob Sparre\} and Levinsen, \{Mogens T.\}",

year = "1997",

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language = "English",

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journal = "Physical Review Letters",

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T1 - Fractal particle trajectories in capillary waves

T2 - Imprint of wavelength

AU - Hansen, Adam E.

AU - Schröder, Elsebeth

AU - Alstrøm, Preben

AU - Andersen, Jacob Sparre

AU - Levinsen, Mogens T.

PY - 1997

Y1 - 1997

N2 - We examine particle trajectories in capillary waves formed on a water surface subject to vertical vibrations. We focus on the role of a distinct length scale present in our experiment, namely, the wavelength λ of the surface waves. We observe non-Brownian particle trajectories with a fractal dimension D different from the random walk value D = 2. A crossover is observed from one anomalous behavior at length scales below λ, to another at larger length scales. Data collapse is shown to be feasible, and scaling functions characterizing the crossover are identified. Our results are compared to those obtained from observations of drifters in the upper ocean. The distinct length scale λ allows us to divide the particle trajectories into flights and traps. The distribution of flight times shows a power-law behavior with an exponent between 2.3 and 3.

AB - We examine particle trajectories in capillary waves formed on a water surface subject to vertical vibrations. We focus on the role of a distinct length scale present in our experiment, namely, the wavelength λ of the surface waves. We observe non-Brownian particle trajectories with a fractal dimension D different from the random walk value D = 2. A crossover is observed from one anomalous behavior at length scales below λ, to another at larger length scales. Data collapse is shown to be feasible, and scaling functions characterizing the crossover are identified. Our results are compared to those obtained from observations of drifters in the upper ocean. The distinct length scale λ allows us to divide the particle trajectories into flights and traps. The distribution of flight times shows a power-law behavior with an exponent between 2.3 and 3.

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DO - 10.1103/PhysRevLett.79.1845

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SN - 0031-9007

VL - 79

SP - 1845

EP - 1848

JO - Physical Review Letters

JF - Physical Review Letters

IS - 10

ER -

Fractal particle trajectories in capillary waves: Imprint of wavelength

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