An External Line Plume next to a Dissolving Ice Face

Craig McConnochie; Ross Kerr

An External Line Plume next to a Dissolving Ice Face

Craig McConnochie, Ross Kerr

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

Abstract

We present experiments that investigate the effect of a turbulent line plume next to a dissolving vertical ice face. The ice face provides a distributed source of buoyancy in addition to the buoyancy flux from the line plume at the base of the ice. The buoyancy flux, Bs is varied from 0.5Bo to 28Bo where Bo is the distributed buoyancy flux from the ice wall without the additional line plume. The plume velocity, ablation velocity of the ice and the temperature at the ice-fluid interface are measured over the height of the ice face. When B is small, the line plume is not dynamically important. However, as B increases the plume transitions to a regime where the distributed buoyancy flux from the ice wall is negligible and the line plume controls the flow. Within this regime the plume velocity is proportional to B1=3 and the ablation velocity increases as B increases

Original language	English
Title of host publication	Proceedings of the 20th Australasian Fluid Mechanics Conference
Place of Publication	Melbourne
Publisher	Australasian Fluid Mechanics Society
Pages	1-4pp
Edition	Peer Reviewed
ISBN (Print)	9781740523776
Publication status	Published - 2016
Event	Australasian Fluid Mechanics Conference - Perth, WA, Australia Duration: 1 Jan 2016 → … http://afms.org.au/proceedings.html

Conference

Conference	Australasian Fluid Mechanics Conference
Country/Territory	Australia
Period	1/01/16 → …
Other	December 5-8 2016
Internet address	http://afms.org.au/proceedings.html

Cite this

@inproceedings{ff2cb71f157d43eab547d29d3b5b3cc8,

title = "An External Line Plume next to a Dissolving Ice Face",

abstract = "We present experiments that investigate the effect of a turbulent line plume next to a dissolving vertical ice face. The ice face provides a distributed source of buoyancy in addition to the buoyancy flux from the line plume at the base of the ice. The buoyancy flux, Bs is varied from 0.5Bo to 28Bo where Bo is the distributed buoyancy flux from the ice wall without the additional line plume. The plume velocity, ablation velocity of the ice and the temperature at the ice-fluid interface are measured over the height of the ice face. When B is small, the line plume is not dynamically important. However, as B increases the plume transitions to a regime where the distributed buoyancy flux from the ice wall is negligible and the line plume controls the flow. Within this regime the plume velocity is proportional to B1=3 and the ablation velocity increases as B increases",

author = "Craig McConnochie and Ross Kerr",

year = "2016",

language = "English",

isbn = "9781740523776",

pages = "1--4pp",

booktitle = "Proceedings of the 20th Australasian Fluid Mechanics Conference",

publisher = "Australasian Fluid Mechanics Society",

edition = "Peer Reviewed",

note = "Australasian Fluid Mechanics Conference ; Conference date: 01-01-2016",

url = "http://afms.org.au/proceedings.html",

}

TY - GEN

T1 - An External Line Plume next to a Dissolving Ice Face

AU - McConnochie, Craig

AU - Kerr, Ross

PY - 2016

Y1 - 2016

N2 - We present experiments that investigate the effect of a turbulent line plume next to a dissolving vertical ice face. The ice face provides a distributed source of buoyancy in addition to the buoyancy flux from the line plume at the base of the ice. The buoyancy flux, Bs is varied from 0.5Bo to 28Bo where Bo is the distributed buoyancy flux from the ice wall without the additional line plume. The plume velocity, ablation velocity of the ice and the temperature at the ice-fluid interface are measured over the height of the ice face. When B is small, the line plume is not dynamically important. However, as B increases the plume transitions to a regime where the distributed buoyancy flux from the ice wall is negligible and the line plume controls the flow. Within this regime the plume velocity is proportional to B1=3 and the ablation velocity increases as B increases

AB - We present experiments that investigate the effect of a turbulent line plume next to a dissolving vertical ice face. The ice face provides a distributed source of buoyancy in addition to the buoyancy flux from the line plume at the base of the ice. The buoyancy flux, Bs is varied from 0.5Bo to 28Bo where Bo is the distributed buoyancy flux from the ice wall without the additional line plume. The plume velocity, ablation velocity of the ice and the temperature at the ice-fluid interface are measured over the height of the ice face. When B is small, the line plume is not dynamically important. However, as B increases the plume transitions to a regime where the distributed buoyancy flux from the ice wall is negligible and the line plume controls the flow. Within this regime the plume velocity is proportional to B1=3 and the ablation velocity increases as B increases

M3 - Conference contribution

SN - 9781740523776

SP - 1

EP - 4

BT - Proceedings of the 20th Australasian Fluid Mechanics Conference

PB - Australasian Fluid Mechanics Society

CY - Melbourne

T2 - Australasian Fluid Mechanics Conference

Y2 - 1 January 2016

ER -