Modeling the topography of the salar de Uyuni, Bolivia, as an equipotential surface of Earth's gravity field

The salar de Uyuni is a massive dry salt lake that lies at the lowest point of an internal drainage basin in the Bolivian Altiplano. A kinematic GPS survey of the salar in September 2002 found a topographic range of only 80 cm over a 54 × 45 km area and subtle surface features that appeared to corre...

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Veröffentlicht in:	Journal of Geophysical Research: Solid Earth 2008-10, Vol.113 (B10), p.n/a
Hauptverfasser:	Borsa, Adrian A., Bills, Bruce G., Minster, Jean-Bernard
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Sprache:	eng
Schlagworte:	Earth sciences Earth, ocean, space Exact sciences and technology geopotential salt flat topography
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creator	Borsa, Adrian A. Bills, Bruce G. Minster, Jean-Bernard
description	The salar de Uyuni is a massive dry salt lake that lies at the lowest point of an internal drainage basin in the Bolivian Altiplano. A kinematic GPS survey of the salar in September 2002 found a topographic range of only 80 cm over a 54 × 45 km area and subtle surface features that appeared to correlate with mapped gravity. In order to confirm the correlation between topography and gravity/geopotential, we use local gravity measurements and the EGM96 global geopotential model to construct a centimeter‐level equipotential surface corresponding to the elevation of the salar. Our comparison of GPS survey elevations with the equipotential surface estimate shows that 63% of the variance of the GPS elevations can be explained by equipotential surface undulations (and long‐wavelength error) in the EGM96 model alone, with an additional 30% explained by the shorter‐wavelength equipotential surface derived from local gravity. In order to establish a physical connection between topography and the geopotential, we also develop and test a simple surface process model that redistributes salt via the dissolution, transport, and redeposition of salt by precipitated water. Forcing within the model pushes the system to evolve toward constant water depth, with the salt surface approximating the shape of the local equipotential surface. Since the model removes almost all topographic relief with respect to the equipotential surface within a matter of decades, it appears that observed (∼5 cm amplitude, ∼5 km wavelength) residual topography is actively maintained by a process independent of gravity‐driven fluid flow.
doi_str_mv	10.1029/2007JB005445
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A kinematic GPS survey of the salar in September 2002 found a topographic range of only 80 cm over a 54 × 45 km area and subtle surface features that appeared to correlate with mapped gravity. In order to confirm the correlation between topography and gravity/geopotential, we use local gravity measurements and the EGM96 global geopotential model to construct a centimeter‐level equipotential surface corresponding to the elevation of the salar. Our comparison of GPS survey elevations with the equipotential surface estimate shows that 63% of the variance of the GPS elevations can be explained by equipotential surface undulations (and long‐wavelength error) in the EGM96 model alone, with an additional 30% explained by the shorter‐wavelength equipotential surface derived from local gravity. In order to establish a physical connection between topography and the geopotential, we also develop and test a simple surface process model that redistributes salt via the dissolution, transport, and redeposition of salt by precipitated water. Forcing within the model pushes the system to evolve toward constant water depth, with the salt surface approximating the shape of the local equipotential surface. 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Geophys. Res</addtitle><description>The salar de Uyuni is a massive dry salt lake that lies at the lowest point of an internal drainage basin in the Bolivian Altiplano. A kinematic GPS survey of the salar in September 2002 found a topographic range of only 80 cm over a 54 × 45 km area and subtle surface features that appeared to correlate with mapped gravity. In order to confirm the correlation between topography and gravity/geopotential, we use local gravity measurements and the EGM96 global geopotential model to construct a centimeter‐level equipotential surface corresponding to the elevation of the salar. Our comparison of GPS survey elevations with the equipotential surface estimate shows that 63% of the variance of the GPS elevations can be explained by equipotential surface undulations (and long‐wavelength error) in the EGM96 model alone, with an additional 30% explained by the shorter‐wavelength equipotential surface derived from local gravity. In order to establish a physical connection between topography and the geopotential, we also develop and test a simple surface process model that redistributes salt via the dissolution, transport, and redeposition of salt by precipitated water. Forcing within the model pushes the system to evolve toward constant water depth, with the salt surface approximating the shape of the local equipotential surface. 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Geophys. Res</addtitle><date>2008-10</date><risdate>2008</risdate><volume>113</volume><issue>B10</issue><epage>n/a</epage><issn>0148-0227</issn><eissn>2156-2202</eissn><abstract>The salar de Uyuni is a massive dry salt lake that lies at the lowest point of an internal drainage basin in the Bolivian Altiplano. A kinematic GPS survey of the salar in September 2002 found a topographic range of only 80 cm over a 54 × 45 km area and subtle surface features that appeared to correlate with mapped gravity. In order to confirm the correlation between topography and gravity/geopotential, we use local gravity measurements and the EGM96 global geopotential model to construct a centimeter‐level equipotential surface corresponding to the elevation of the salar. Our comparison of GPS survey elevations with the equipotential surface estimate shows that 63% of the variance of the GPS elevations can be explained by equipotential surface undulations (and long‐wavelength error) in the EGM96 model alone, with an additional 30% explained by the shorter‐wavelength equipotential surface derived from local gravity. In order to establish a physical connection between topography and the geopotential, we also develop and test a simple surface process model that redistributes salt via the dissolution, transport, and redeposition of salt by precipitated water. Forcing within the model pushes the system to evolve toward constant water depth, with the salt surface approximating the shape of the local equipotential surface. Since the model removes almost all topographic relief with respect to the equipotential surface within a matter of decades, it appears that observed (∼5 cm amplitude, ∼5 km wavelength) residual topography is actively maintained by a process independent of gravity‐driven fluid flow.</abstract><cop>Washington, DC</cop><pub>Blackwell Publishing Ltd</pub><doi>10.1029/2007JB005445</doi><tpages>21</tpages><oa>free_for_read</oa></addata></record>
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subjects	Earth sciences Earth, ocean, space Exact sciences and technology geopotential salt flat topography
title	Modeling the topography of the salar de Uyuni, Bolivia, as an equipotential surface of Earth's gravity field
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