2007
DOI: 10.1016/j.gca.2006.12.006
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Field experiments yield new insights into gas exchange and excess air formation in natural porous media

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Cited by 69 publications
(62 citation statements)
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References 21 publications
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“…doi:10. 1016/j.gca.2008.02.012 (1987) together with an 40 Ar diffusion coefficient estimated by extrapolation of their results (Ballentine et al, 2002;Kipfer et al, 2002;Rü bel et al, 2002;Holocher et al, 2003;Peeters et al, 2003;Price et al, 2003;Poreda et al, 2004;Brennwald et al, 2005;Hendry et al, 2005;Strassmann et al, 2005;Zhou et al, 2005;Hall et al, 2006;Ingram et al, 2007;Klump et al, 2007;Rodehacke et al, 2007). Diffusion coefficients of minor noble gas isotopes in liquid water for which no data exist then have routinely been estimated using the kinetic-theory model D / 1/l 0.5 [l is the solvent-solute reduced mass, l = mm 0 /(m+m 0 ), if m and m 0 are solute and solvent molecular masses (LaBolle et al, 2006)] or, more commonly, using the 'square-root' relation…”
Section: Introductionmentioning
confidence: 90%
“…doi:10. 1016/j.gca.2008.02.012 (1987) together with an 40 Ar diffusion coefficient estimated by extrapolation of their results (Ballentine et al, 2002;Kipfer et al, 2002;Rü bel et al, 2002;Holocher et al, 2003;Peeters et al, 2003;Price et al, 2003;Poreda et al, 2004;Brennwald et al, 2005;Hendry et al, 2005;Strassmann et al, 2005;Zhou et al, 2005;Hall et al, 2006;Ingram et al, 2007;Klump et al, 2007;Rodehacke et al, 2007). Diffusion coefficients of minor noble gas isotopes in liquid water for which no data exist then have routinely been estimated using the kinetic-theory model D / 1/l 0.5 [l is the solvent-solute reduced mass, l = mm 0 /(m+m 0 ), if m and m 0 are solute and solvent molecular masses (LaBolle et al, 2006)] or, more commonly, using the 'square-root' relation…”
Section: Introductionmentioning
confidence: 90%
“…Tidal inundation of the marsh platform could increase pressure in the pore space in this manner. The phenomenon of 'excess air,' or supersaturation caused by the trapping and subsequent partial or complete dissolution of air bubbles is sometimes invoked to explain groundwater supersaturations of noble gases (Heaton and Vogel 1981;Klump et al 2007); if air in the pore space was completely dissolved, the expected ratio of Ne/He in the porewater would be 3.47, and that of Xe/Ne 0.005. The measured ratios in the porewater are instead 4.25 (Ne/He) and 0.060 (Xe/Ne), with more soluble gases more enriched relative to the less soluble gases than expected for complete dissolution of trapped air, consistent with an equilibrium process (and thus the uniform saturation state of the noble gases).…”
Section: Noble Gasesmentioning
confidence: 99%
“…In contrary, in the framework of the kinetic theory, the diffusion coefficient of a dissolved species is mass dependent and the ratio between two diffusion coefficients of two isotopically distinct species is proportional to the inverse square root of their reduced masses: For diffusing gases Eq. (2) can be simplified by assuming that the mass of the molecules of the medium (M i ) is infinitively large in comparison to the diffusing molecules (M i ) m i ) (Ballentine et al, 2002;Lippmann et al, 2003;Peeters et al, 2003;Strassmann et al, 2005;Zhou et al, 2005;Richter et al, 2006;Klump et al, 2007;Bourg and Sposito, 2008). Therefore, the reduced mass in Eq.…”
Section: Introductionmentioning
confidence: 99%