Mars outflow channels: A reappraisal of the estimation of water flow speeds from water depths, regional slopes and channel floor properties.

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Mars outflow channels: A reappraisal of the estimation of water flow speeds from water depths, regional slopes and channel floor properties. / Wilson, Lionel; Ghatan, G.; Head, James W. et al.
In: Journal of Geophysical Research: Planets, Vol. 109, 09.2004, p. E09003.

Research output: Contribution to Journal/Magazine › Journal article › peer-review

Harvard

Wilson, L, Ghatan, G, Head, JW & Mitchell, KL 2004, 'Mars outflow channels: A reappraisal of the estimation of water flow speeds from water depths, regional slopes and channel floor properties.', Journal of Geophysical Research: Planets, vol. 109, pp. E09003. https://doi.org/10.1029/2004JE002281

APA

Wilson, L., Ghatan, G., Head, J. W., & Mitchell, K. L. (2004). Mars outflow channels: A reappraisal of the estimation of water flow speeds from water depths, regional slopes and channel floor properties. Journal of Geophysical Research: Planets, 109, E09003. https://doi.org/10.1029/2004JE002281

Vancouver

Wilson L, Ghatan G, Head JW, Mitchell KL. Mars outflow channels: A reappraisal of the estimation of water flow speeds from water depths, regional slopes and channel floor properties. Journal of Geophysical Research: Planets. 2004 Sept;109:E09003. doi: 10.1029/2004JE002281

Author

Wilson, Lionel ; Ghatan, G. ; Head, James W. et al. / Mars outflow channels: A reappraisal of the estimation of water flow speeds from water depths, regional slopes and channel floor properties. In: Journal of Geophysical Research: Planets. 2004 ; Vol. 109. pp. E09003.

Bibtex

@article{42e4c3128be14df9819325e9cc234abd,

title = "Mars outflow channels: A reappraisal of the estimation of water flow speeds from water depths, regional slopes and channel floor properties.",

abstract = "Methods used so far to assess the flow velocities of the water commonly assumed to be responsible for forming the major outflow channel systems on Mars have relied widely on various versions of the Manning equation. This has led to problems in allowing for the difference between the accelerations due to gravity on Mars and Earth and for the differences of scale between Martian floods and most river systems on Earth. We reanalyze the problem of estimating water flow velocities in Martian outflow channels using equations based on the Darcy-Weisbach friction factor instead of the Manning n factor. We give simplified formulae appropriate to Mars for the Darcy-Weisbach friction coefficient as a function of bedrock size distribution. For a given channel floor slope and water flood depth, similar mean flow velocities are implied for a wide range of values of the ratio of bed roughness to water depth relevant to Martian outflow channels. Using a recent rederivation of Manning's equation based on turbulence theory, we obtain a new value of 0.0545 s m−1/3 for the Manning n coefficient appropriate to Martian channels and show that previous analyses have generally overestimated (though in some cases underestimated) water flow velocities on Mars by a factor of order two. Combining the consequences of this flow velocity overestimate with likely overestimates of flow depth from assuming bank-full flow, we show that discharges may have been overestimated by a factor of up to 25, leading to corresponding overestimates of subsurface aquifer permeabilities, rates of filling of depressions with water, and grain sizes of sediments on channel floors. Despite the availability of an improved value for the Manning n coefficient for Mars, we strongly recommend that modified forms of the original version of the Manning equation should be replaced by the modern form or, preferably, by the Darcy-Weisbach equation in future work.",

keywords = "Mars, outflow channels, water.",

author = "Lionel Wilson and G. Ghatan and Head, {James W.} and Mitchell, {K. L.}",

note = "Wilson and post-doc Mitchell provided the physics and mathematics, Ghatan and Head (Brown Univ.) the observations. Improved estimates of water volume fluxes through giant outflow channels on Mars imply that the crust of Mars must be heavily fractured and provide a focus for planning future Mars geophysics missions. RAE_import_type : Journal article RAE_uoa_type : Earth Systems and Environmental Sciences",

year = "2004",

month = sep,

doi = "10.1029/2004JE002281",

language = "English",

volume = "109",

pages = "E09003",

journal = "Journal of Geophysical Research: Planets",

issn = "2169-9100",

publisher = "Blackwell Publishing Ltd",

}

RIS

TY - JOUR

T1 - Mars outflow channels: A reappraisal of the estimation of water flow speeds from water depths, regional slopes and channel floor properties.

AU - Wilson, Lionel

AU - Ghatan, G.

AU - Head, James W.

AU - Mitchell, K. L.

N1 - Wilson and post-doc Mitchell provided the physics and mathematics, Ghatan and Head (Brown Univ.) the observations. Improved estimates of water volume fluxes through giant outflow channels on Mars imply that the crust of Mars must be heavily fractured and provide a focus for planning future Mars geophysics missions. RAE_import_type : Journal article RAE_uoa_type : Earth Systems and Environmental Sciences

PY - 2004/9

Y1 - 2004/9

N2 - Methods used so far to assess the flow velocities of the water commonly assumed to be responsible for forming the major outflow channel systems on Mars have relied widely on various versions of the Manning equation. This has led to problems in allowing for the difference between the accelerations due to gravity on Mars and Earth and for the differences of scale between Martian floods and most river systems on Earth. We reanalyze the problem of estimating water flow velocities in Martian outflow channels using equations based on the Darcy-Weisbach friction factor instead of the Manning n factor. We give simplified formulae appropriate to Mars for the Darcy-Weisbach friction coefficient as a function of bedrock size distribution. For a given channel floor slope and water flood depth, similar mean flow velocities are implied for a wide range of values of the ratio of bed roughness to water depth relevant to Martian outflow channels. Using a recent rederivation of Manning's equation based on turbulence theory, we obtain a new value of 0.0545 s m−1/3 for the Manning n coefficient appropriate to Martian channels and show that previous analyses have generally overestimated (though in some cases underestimated) water flow velocities on Mars by a factor of order two. Combining the consequences of this flow velocity overestimate with likely overestimates of flow depth from assuming bank-full flow, we show that discharges may have been overestimated by a factor of up to 25, leading to corresponding overestimates of subsurface aquifer permeabilities, rates of filling of depressions with water, and grain sizes of sediments on channel floors. Despite the availability of an improved value for the Manning n coefficient for Mars, we strongly recommend that modified forms of the original version of the Manning equation should be replaced by the modern form or, preferably, by the Darcy-Weisbach equation in future work.

AB - Methods used so far to assess the flow velocities of the water commonly assumed to be responsible for forming the major outflow channel systems on Mars have relied widely on various versions of the Manning equation. This has led to problems in allowing for the difference between the accelerations due to gravity on Mars and Earth and for the differences of scale between Martian floods and most river systems on Earth. We reanalyze the problem of estimating water flow velocities in Martian outflow channels using equations based on the Darcy-Weisbach friction factor instead of the Manning n factor. We give simplified formulae appropriate to Mars for the Darcy-Weisbach friction coefficient as a function of bedrock size distribution. For a given channel floor slope and water flood depth, similar mean flow velocities are implied for a wide range of values of the ratio of bed roughness to water depth relevant to Martian outflow channels. Using a recent rederivation of Manning's equation based on turbulence theory, we obtain a new value of 0.0545 s m−1/3 for the Manning n coefficient appropriate to Martian channels and show that previous analyses have generally overestimated (though in some cases underestimated) water flow velocities on Mars by a factor of order two. Combining the consequences of this flow velocity overestimate with likely overestimates of flow depth from assuming bank-full flow, we show that discharges may have been overestimated by a factor of up to 25, leading to corresponding overestimates of subsurface aquifer permeabilities, rates of filling of depressions with water, and grain sizes of sediments on channel floors. Despite the availability of an improved value for the Manning n coefficient for Mars, we strongly recommend that modified forms of the original version of the Manning equation should be replaced by the modern form or, preferably, by the Darcy-Weisbach equation in future work.

KW - Mars

KW - outflow channels

KW - water.

U2 - 10.1029/2004JE002281

DO - 10.1029/2004JE002281

M3 - Journal article

VL - 109

SP - E09003

JO - Journal of Geophysical Research: Planets

JF - Journal of Geophysical Research: Planets

SN - 2169-9100

ER -

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