Shoaling internal waves may reduce gravity current transport

Charlie A.R. Hogg; Galen C. Egan; Nicholas T. Ouellette; Jeffrey R. Koseff

doi:10.1007/s10652-017-9554-8

Shoaling internal waves may reduce gravity current transport

Charlie A.R. Hogg, Galen C. Egan, Nicholas T. Ouellette, Jeffrey R. Koseff

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

7 Scopus citations

Abstract

Gravity currents descending along slopes have typically been studied in quiescent environments, despite the fact that in many geophysical settings there is significant externally driven motion. Here we investigate how the head of a gravity current is influenced by interfacial internal waves at the pycnocline of a two-layer ambient water column. Our experimental measurements show that larger amplitude internal waves, interacting with the gravity current, reduce both the mass transport by the gravity current and its thickness. These results suggest that the ambient internal wave field should be considered when estimating transport by gravity currents in geophysical settings with strong internal waves, such as lakes and the coastal ocean.

Original language	English (US)
Pages (from-to)	383-394
Number of pages	12
Journal	Environmental Fluid Mechanics
Volume	18
Issue number	2
DOIs	https://doi.org/10.1007/s10652-017-9554-8
State	Published - Apr 1 2018
Externally published	Yes

All Science Journal Classification (ASJC) codes

Environmental Chemistry
Water Science and Technology

Keywords

Coastal ocean processes
Desalination
Gravity currents
Internal waves
Limnology
River inflows

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10.1007/s10652-017-9554-8

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title = "Shoaling internal waves may reduce gravity current transport",

abstract = "Gravity currents descending along slopes have typically been studied in quiescent environments, despite the fact that in many geophysical settings there is significant externally driven motion. Here we investigate how the head of a gravity current is influenced by interfacial internal waves at the pycnocline of a two-layer ambient water column. Our experimental measurements show that larger amplitude internal waves, interacting with the gravity current, reduce both the mass transport by the gravity current and its thickness. These results suggest that the ambient internal wave field should be considered when estimating transport by gravity currents in geophysical settings with strong internal waves, such as lakes and the coastal ocean.",

keywords = "Coastal ocean processes, Desalination, Gravity currents, Internal waves, Limnology, River inflows",

author = "Hogg, {Charlie A.R.} and Egan, {Galen C.} and Ouellette, {Nicholas T.} and Koseff, {Jeffrey R.}",

note = "Publisher Copyright: {\textcopyright} 2017, Springer Science+Business Media B.V.",

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doi = "10.1007/s10652-017-9554-8",

language = "English (US)",

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TY - JOUR

T1 - Shoaling internal waves may reduce gravity current transport

AU - Hogg, Charlie A.R.

AU - Egan, Galen C.

AU - Ouellette, Nicholas T.

AU - Koseff, Jeffrey R.

PY - 2018/4/1

Y1 - 2018/4/1

N2 - Gravity currents descending along slopes have typically been studied in quiescent environments, despite the fact that in many geophysical settings there is significant externally driven motion. Here we investigate how the head of a gravity current is influenced by interfacial internal waves at the pycnocline of a two-layer ambient water column. Our experimental measurements show that larger amplitude internal waves, interacting with the gravity current, reduce both the mass transport by the gravity current and its thickness. These results suggest that the ambient internal wave field should be considered when estimating transport by gravity currents in geophysical settings with strong internal waves, such as lakes and the coastal ocean.

AB - Gravity currents descending along slopes have typically been studied in quiescent environments, despite the fact that in many geophysical settings there is significant externally driven motion. Here we investigate how the head of a gravity current is influenced by interfacial internal waves at the pycnocline of a two-layer ambient water column. Our experimental measurements show that larger amplitude internal waves, interacting with the gravity current, reduce both the mass transport by the gravity current and its thickness. These results suggest that the ambient internal wave field should be considered when estimating transport by gravity currents in geophysical settings with strong internal waves, such as lakes and the coastal ocean.

KW - Coastal ocean processes

KW - Desalination

KW - Gravity currents

KW - Internal waves

KW - Limnology

KW - River inflows

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Shoaling internal waves may reduce gravity current transport

Abstract

All Science Journal Classification (ASJC) codes

Keywords

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