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W763944896 endingPage "78" @default.
W763944896 startingPage "63" @default.
W763944896 abstract "Vanadium (V) concentrations were measured along the flow paths in two contrasting aquifer systems to study how changing solution composition and redox conditions affect V cycling and transport in groundwater flow systems. The Oasis Valley groundwater system in Nevada is an unconfined system where groundwaters generally remain oxic along the flow path, whereas the Carrizo Sand aquifer is a deep, confined coastal plain aquifer in Texas that contains well-defined Fe(III) and SO42 − reduction zones along the flow path. Speciation modeling predicts that in groundwaters from the Oasis Valley, V chiefly occurs as the vanadate oxyanion (e.g., H2VO4−, HVO42 −), which is mobile along the entire flow path because of vanadate's solubility in oxic and alkaline waters. Furthermore, the data indicate that V concentrations increase in groundwaters along the flow path suggesting that mineral dissolution and/or desorption reactions progressively contribute V to groundwaters of the Oasis Valley system. Geochemical modeling is consistent with dissolution of mafic phenocrysts that are common in the local tuffaceous aquifer rocks as a probable source of V to Oasis Valley groundwaters. Within the Carrizo Sand aquifer, groundwater V concentrations decrease with flow beyond the recharge zone and into the confined portion of the aquifer. Thereafter, total V concentrations remain low and relatively constant along the remainder of the studied flow path, exhibiting no systematic variations across the Fe(III) and SO42 − reduction zones. Groundwaters from the Carrizo Sand aquifer are generally reducing, and as such, geochemical modeling suggests that both V(V) and V(IV) species occur in Carrizo Sand groundwaters, and furthermore, that the proportion of V(IV) species increases concurrent with the decrease in total V concentrations along the flow path. Results from sequential extraction experiments on Carrizo Sand aquifer sediment samples suggest that V adsorption onto Fe(III)/Mn(IV) oxides/oxyhydroxides acts to decrease the aqueous V concentrations in Carrizo Sand groundwater. Furthermore, geochemical modeling is consistent with complexation of V(IV) with dissolved organic matter (DOM) within the Carrizo Sand aquifer groundwaters, which, owing to the low DOM concentrations, appears to buffer V at low, but relatively constant concentrations within the confined and reducing Carrizo Sand groundwaters. These results support previous reports of V(IV)–DOM binding and imply that aquifer material maintains an essential role in not only determining the availability of V to enter aqueous solution but also in influencing partitioning between solid and aqueous phases." @default.
W763944896 created "2016-06-24" @default.
W763944896 creator A5035712617 @default.
W763944896 creator A5059117418 @default.
W763944896 creator A5059510663 @default.
W763944896 creator A5075587516 @default.
W763944896 date "2015-09-01" @default.
W763944896 modified "2023-10-13" @default.
W763944896 title "Vanadium geochemistry along groundwater flow paths in contrasting aquifers of the United States: Carrizo Sand (Texas) and Oasis Valley (Nevada) aquifers" @default.
W763944896 cites W1249284425 @default.
W763944896 cites W1520694267 @default.
W763944896 cites W1642565483 @default.
W763944896 cites W1968945335 @default.
W763944896 cites W1971952269 @default.
W763944896 cites W1973877777 @default.
W763944896 cites W1975944352 @default.
W763944896 cites W1976214358 @default.
W763944896 cites W1978777441 @default.
W763944896 cites W1981026196 @default.
W763944896 cites W1981437501 @default.
W763944896 cites W1983128140 @default.
W763944896 cites W1988637513 @default.
W763944896 cites W1989742232 @default.
W763944896 cites W1993304547 @default.
W763944896 cites W1993969693 @default.
W763944896 cites W1996363387 @default.
W763944896 cites W1998027180 @default.
W763944896 cites W2002398396 @default.
W763944896 cites W2003927281 @default.
W763944896 cites W2005985500 @default.
W763944896 cites W2009000226 @default.
W763944896 cites W2009713287 @default.
W763944896 cites W2011034294 @default.
W763944896 cites W2013598020 @default.
W763944896 cites W2016759770 @default.
W763944896 cites W2017737086 @default.
W763944896 cites W2018235059 @default.
W763944896 cites W2018795626 @default.
W763944896 cites W2023814410 @default.
W763944896 cites W2024690990 @default.
W763944896 cites W2024992079 @default.
W763944896 cites W2025897066 @default.
W763944896 cites W2026829202 @default.
W763944896 cites W2027601495 @default.
W763944896 cites W2029926888 @default.
W763944896 cites W2034481253 @default.
W763944896 cites W2035048619 @default.
W763944896 cites W2036014873 @default.
W763944896 cites W2036786881 @default.
W763944896 cites W2037716169 @default.
W763944896 cites W2040675462 @default.
W763944896 cites W2040873773 @default.
W763944896 cites W2046957942 @default.
W763944896 cites W2049532691 @default.
W763944896 cites W2049954369 @default.
W763944896 cites W2050646061 @default.
W763944896 cites W2052393515 @default.
W763944896 cites W2052664974 @default.
W763944896 cites W2053137298 @default.
W763944896 cites W2057391595 @default.
W763944896 cites W2060201165 @default.
W763944896 cites W2062480556 @default.
W763944896 cites W2067423927 @default.
W763944896 cites W2071136989 @default.
W763944896 cites W2072098845 @default.
W763944896 cites W2075944686 @default.
W763944896 cites W2077242576 @default.
W763944896 cites W2078056766 @default.
W763944896 cites W2078772463 @default.
W763944896 cites W2081673195 @default.
W763944896 cites W2082112579 @default.
W763944896 cites W2084081479 @default.
W763944896 cites W2084475519 @default.
W763944896 cites W2086127417 @default.
W763944896 cites W2087438337 @default.
W763944896 cites W2087666238 @default.
W763944896 cites W2090467640 @default.
W763944896 cites W2090524817 @default.
W763944896 cites W2093048241 @default.
W763944896 cites W2094142381 @default.
W763944896 cites W2095772101 @default.
W763944896 cites W2098026146 @default.
W763944896 cites W2122119168 @default.
W763944896 cites W2126221803 @default.
W763944896 cites W2130794334 @default.
W763944896 cites W2131320965 @default.
W763944896 cites W2137397091 @default.
W763944896 cites W2143964153 @default.
W763944896 cites W2150663073 @default.
W763944896 cites W2166657645 @default.
W763944896 cites W2167302582 @default.
W763944896 cites W2196211697 @default.
W763944896 cites W2326604812 @default.
W763944896 cites W40927942 @default.
W763944896 doi "https://doi.org/10.1016/j.chemgeo.2015.05.024" @default.
W763944896 hasPublicationYear "2015" @default.
W763944896 type Work @default.
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