Floating brine crusts, reduction of evaporation and possible replacement of fresh water to control dust from Owens Lake bed, California

Owens Lake, California, a saline terminal lake desiccated after diversion of its water source, was formerly the single largest anthropogenic source of fugitive dust in North America. Over 100 billion m −3 yr −1 of fresh water are projected to be used for mandated dust control in over 100 km 2 of con...

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Published in	Journal of hydrology (Amsterdam) Vol. 392; no. 3; pp. 211 - 218
Main Authors	Groeneveld, D.P., Huntington, J.L., Barz, D.D.
Format	Journal Article
Language	English
Published	Kidlington Elsevier B.V 15.10.2010 [Amsterdam; New York]: Elsevier Elsevier
Subjects	arid zones atmospheric precipitation Basins Brine California Crusts Deposits Dust control Earth sciences Earth, ocean, space emissions Evaporation Exact sciences and technology Floating structures Fresh water freshwater Hydrology Hydrology. Hydrogeology Lakes Saline playa Saltcrust Sodium chloride sodium sulfate Static chamber United States California Static chamber Saline playa Evaporation Saltcrust Brine salt climate sulfates North America chemically precipitated rocks evaporites surface water sedimentary rocks precipitation brines playas encrustations lakes sodium carbonate evaporite deposits fresh water evaporation dust sodium chloride
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Abstract	Owens Lake, California, a saline terminal lake desiccated after diversion of its water source, was formerly the single largest anthropogenic source of fugitive dust in North America. Over 100 billion m −3 yr −1 of fresh water are projected to be used for mandated dust control in over 100 km 2 of constructed basins required to be wetted to curtail emissions. An extensive evaporite deposit is located at the lake’s topographic low and adjacent to the dust control basins. Because this deposit is non-dust-emissive, it was investigated as a potential replacement for the fresh water used in dust control. The deposit consists of precipitated layers of sodium carbonate and sulfate bathed by, and covered with brine dominated by sodium chloride perennially covered with floating salt crust. Evaporation ( E) rates through this crust were measured using a static chamber during the period of highest evaporative demand, late June and early July, 2009. Annualized total E from these measurements was significantly below average annual precipitation, thus ensuring that such salt deposits naturally remain wet throughout the year, despite the arid climate. Because it remains wetted, the evaporite deposit may therefore have the potential to replace fresh water to achieve dust control at near zero water use.
AbstractList	Owens Lake, California, a saline terminal lake desiccated after diversion of its water source, was formerly the single largest anthropogenic source of fugitive dust in North America. Over 100 billion m −3 yr −1 of fresh water are projected to be used for mandated dust control in over 100 km 2 of constructed basins required to be wetted to curtail emissions. An extensive evaporite deposit is located at the lake’s topographic low and adjacent to the dust control basins. Because this deposit is non-dust-emissive, it was investigated as a potential replacement for the fresh water used in dust control. The deposit consists of precipitated layers of sodium carbonate and sulfate bathed by, and covered with brine dominated by sodium chloride perennially covered with floating salt crust. Evaporation ( E) rates through this crust were measured using a static chamber during the period of highest evaporative demand, late June and early July, 2009. Annualized total E from these measurements was significantly below average annual precipitation, thus ensuring that such salt deposits naturally remain wet throughout the year, despite the arid climate. Because it remains wetted, the evaporite deposit may therefore have the potential to replace fresh water to achieve dust control at near zero water use. Owens Lake, California, a saline terminal lake desiccated after diversion of its water source, was formerly the single largest anthropogenic source of fugitive dust in North America. Over 100billion m⁻³ yr⁻¹ of fresh water are projected to be used for mandated dust control in over 100km² of constructed basins required to be wetted to curtail emissions. An extensive evaporite deposit is located at the lake's topographic low and adjacent to the dust control basins. Because this deposit is non-dust-emissive, it was investigated as a potential replacement for the fresh water used in dust control. The deposit consists of precipitated layers of sodium carbonate and sulfate bathed by, and covered with brine dominated by sodium chloride perennially covered with floating salt crust. Evaporation (E) rates through this crust were measured using a static chamber during the period of highest evaporative demand, late June and early July, 2009. Annualized total E from these measurements was significantly below average annual precipitation, thus ensuring that such salt deposits naturally remain wet throughout the year, despite the arid climate. Because it remains wetted, the evaporite deposit may therefore have the potential to replace fresh water to achieve dust control at near zero water use. Owens Lake, California, a saline terminal lake desiccated after diversion of its water source, was formerly the single largest anthropogenic source of fugitive dust in North America. Over 100billion m super(-3)yr super(-1) of fresh water are projected to be used for mandated dust control in over 100km super(2) of constructed basins required to be wetted to curtail emissions. An extensive evaporite deposit is located at the lake's topographic low and adjacent to the dust control basins. Because this deposit is non-dust-emissive, it was investigated as a potential replacement for the fresh water used in dust control. The deposit consists of precipitated layers of sodium carbonate and sulfate bathed by, and covered with brine dominated by sodium chloride perennially covered with floating salt crust. Evaporation (E) rates through this crust were measured using a static chamber during the period of highest evaporative demand, late June and early July, 2009. Annualized total E from these measurements was significantly below average annual precipitation, thus ensuring that such salt deposits naturally remain wet throughout the year, despite the arid climate. Because it remains wetted, the evaporite deposit may therefore have the potential to replace fresh water to achieve dust control at near zero water use.
Author	Barz, D.D. Huntington, J.L. Groeneveld, D.P.
Author_xml	– sequence: 1 givenname: D.P. surname: Groeneveld fullname: Groeneveld, D.P. email: David@HydroBioARS.com organization: HydroBio, Advanced Remote Sensing, Santa Fe, NM, United States – sequence: 2 givenname: J.L. surname: Huntington fullname: Huntington, J.L. organization: Desert Research Institute, Reno, NV, United States – sequence: 3 givenname: D.D. surname: Barz fullname: Barz, D.D. organization: HydroBio, Advanced Remote Sensing, Santa Fe, NM, United States
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Keywords	Static chamber Saline playa Evaporation Saltcrust Brine salt climate sulfates North America chemically precipitated rocks evaporites surface water sedimentary rocks precipitation brines playas encrustations lakes sodium carbonate evaporite deposits fresh water evaporation dust sodium chloride
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Snippet	Owens Lake, California, a saline terminal lake desiccated after diversion of its water source, was formerly the single largest anthropogenic source of fugitive...
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SubjectTerms	arid zones atmospheric precipitation Basins Brine California Crusts Deposits Dust control Earth sciences Earth, ocean, space emissions Evaporation Exact sciences and technology Floating structures Fresh water freshwater Hydrology Hydrology. Hydrogeology Lakes Saline playa Saltcrust Sodium chloride sodium sulfate Static chamber
Title	Floating brine crusts, reduction of evaporation and possible replacement of fresh water to control dust from Owens Lake bed, California
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