Stable isotope studies on the origin and geological history of water and salts in the Lake Vanda area, Antarctica.

Nakai, Nobuyuki; Wada, Hideki; Kiyosu, Yasuhiro; Takimoto, Mikio

doi:10.2343/geochemj.9.7

Cited by 62 publications

(31 citation statements)

References 20 publications

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“…Lake Bonney in Taylor Valley and Lake Vanda in Wright Valley retain hypersaline deep waters with salinities above 100 g/kg (L Bonney, west lobe and L Vanda) and 200 g/kg (L Bonney, east lobe). Based on the chemical and isotopic profiles of these lakes, several investigators (Hendy et al 1977;Lyons et al 1998a;Matsubaya et al 1979;Nakai et al 1975;Ragotzkie and Friedman 1965;Torii and Yamagata 1981) interpreted that the saline, deep waters were formed as a result of the evaporation of lakes to small hypersaline icefree ponds or perhaps to near dryness during a colder and drier climate in the past. Lake Bonney is at least 300-ky old and Lyons et al (2005) suggested that the hypolimnia of Lake Bonney are remnants of a marine fjord of Miocene time.…”

Section: Mcmurdo Dry Valleysmentioning

confidence: 99%

Isotopic Evolution of Saline Lakes in the Low-Latitude and Polar Regions

Horita

2008

Aquat Geochem

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Isotopic fractionations associated with two primary processes (evaporation and freezing of water) are discussed, which are responsible for the formation and evolution of saline lakes in deserts from both low-latitude and the Polar regions. In an evaporative system, atmospheric parameters (humidity and isotopic composition of water vapor) have strong influence on the isotopic behavior of saline lakes, and in a freezing system, salinity build-up largely controls the extent of freezing and associated isotope fractionation. In both systems, salinity has a direct impact on the isotopic evolution of saline lakes. It is proposed that a steady-state ''terminal lake'' model with short-term hydrologic and environmental perturbations can serve as a useful framework for investigating both evaporative and freezing processes of perennial saline lakes. Through re-assessment of own work and literature data for saline lakes, it was demonstrated that effective uses of the isotope activity compositions of brines and salinity-chemistry data could reveal dynamic changes and evolution in the isotopic compositions of saline lakes in response to hydrologic and environmental changes. The residence time of isotopic water molecules in lakes determines the nature of responses in the isotopic compositions following perturbations in the water and isotope balances (e.g., dilution by inflow, water deficit by increased evaporation, and/ or reduction in inflow). The isotopic profiles of some saline lakes from the Polar regions show that they switched the two contrasting modes of operation between evaporative and freezing systems, in response to climate and hydrological changes in the past.

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Section: Mcmurdo Dry Valleysmentioning

confidence: 99%

Isotopic Evolution of Saline Lakes in the Low-Latitude and Polar Regions

Horita

2008

Aquat Geochem

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“…Salt residues from wind-blown sprays are a widespread phenomenon on Antarctic boulders and within soils. Carbon and oxygen isotopic measurements (Nakai et al, 1975) of surficial calcite coatings on rocks from the Wright Dry Valley region of Antarctica display a range in Ol3C (-14.4 to + 17.60/00) and 0 18 0 (-0.4 to + 22.30/00), with different boulders from the same locality showing a large variation. The total range easily encompasses the values obtained for the first generation of bicarbonates from LEW 85320 measured by this study and Gooding et al (1988b), and its local inconsistency may explain the discrepancy between the results obtained by the two sets of investigators.…”

Section: Discussionmentioning

confidence: 99%

Untitled

1989

Meteoritics

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Abstract-Isotopic analysis of nesquehonite recovered from the surface of the LEW 85320 H5 ordinary chondrite shows that the Ol3C and 0 18 0 values of the two generations of bicarbonate (Antarctic and Texas) are different: 013C = + 7.90/00 and +4.20/00; 0 18 0 = +17.90/00 and +12.10/00 respectively. Carbon isotopic compositions are consistent with equilibrium formation from atmospheric carbon dioxide at -2 ± 4 "C (Antarctic) and + 16 ± 4 ·C (Texas). Oxygen isotopic data imply that the water required for nesquehonite precipitation was derived from atmospheric water vapour or glacial meltwater which had locally exchanged with silicates, either in the meteorite or in underlying bedrock. Although carbonates with similar 013C values have been identified in the SNC meteorites EETA 79001 and Nakhla, petrographic and temperature constraints argue against their simply being terrestrial weathering products.

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“…2) On the contrary, it may be argued that Antarctic meteorites are subjected to terrestrial carbonate contamination with heavy S13C by weathering (e.g., Velbel et al, 1991;Miyamoto, 1991). Most S13C values of surface carbonate on terrestrial Antarctic materials are lower (-14.4 to +17.6%o; Nakai et al, 1975) than those of indig enous carbonate in carbonaceous chondrites (+20 to 60%o, Clayton, 1963;Grady et al, 1988). Grady et al (1988) (Table 2).…”

Section: Differences In Carbon Content and Isotope Ratio Between Antamentioning

confidence: 99%