Gravity currents in aquatic canopies

Y  Tanino; H M  Nepf; P S  Kulis

doi:10.1029/2005WR004216

Gravity currents in aquatic canopies

Y Tanino, H M Nepf, P S Kulis

Engineering

Massachusetts Institute of Technology

Research output: Contribution to journal › Article › peer-review

65 Citations (Scopus)

Abstract

[1] A lock exchange experiment is used to investigate the propagation of gravity currents through a random array of rigid, emergent cylinders which represents a canopy of aquatic plants. As canopy drag increases, the propagating front varies from the classic profile of an unobstructed gravity current to a triangular profile. Unlike the unobstructed lock exchange, the gravity current in the canopy decelerates with time as the front lengthens. Two drag-dominated regimes associated with linear and nonlinear drag laws are identified. The theoretical expression for toe velocity is supported by observed values. Empirical criteria are developed to predict the current regime from the cylinder Reynolds number and the array density.

Original language	English
Article number	W12402
Number of pages	9
Journal	Water Resources Research
Volume	41
Issue number	12
DOIs	https://doi.org/10.1029/2005WR004216
Publication status	Published - 1 Dec 2005

Keywords

drag
lock exchange
thermal exchange
vegetated flows

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10.1029/2005WR004216

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abstract = "[1] A lock exchange experiment is used to investigate the propagation of gravity currents through a random array of rigid, emergent cylinders which represents a canopy of aquatic plants. As canopy drag increases, the propagating front varies from the classic profile of an unobstructed gravity current to a triangular profile. Unlike the unobstructed lock exchange, the gravity current in the canopy decelerates with time as the front lengthens. Two drag-dominated regimes associated with linear and nonlinear drag laws are identified. The theoretical expression for toe velocity is supported by observed values. Empirical criteria are developed to predict the current regime from the cylinder Reynolds number and the array density.",

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AB - [1] A lock exchange experiment is used to investigate the propagation of gravity currents through a random array of rigid, emergent cylinders which represents a canopy of aquatic plants. As canopy drag increases, the propagating front varies from the classic profile of an unobstructed gravity current to a triangular profile. Unlike the unobstructed lock exchange, the gravity current in the canopy decelerates with time as the front lengthens. Two drag-dominated regimes associated with linear and nonlinear drag laws are identified. The theoretical expression for toe velocity is supported by observed values. Empirical criteria are developed to predict the current regime from the cylinder Reynolds number and the array density.

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KW - lock exchange

KW - thermal exchange

KW - vegetated flows

U2 - 10.1029/2005WR004216

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JO - Water Resources Research

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Gravity currents in aquatic canopies

Abstract

Keywords

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