Aquatic geochemistry

Lawrence, M.G., Jupiter, S.D., Kamber, B. S. 2006. Aquatic geochemistry of the rare earth elements and yttrium in the Pioneer River catchment, Australia. Marine and Freshwater Research, 57, 725-736. [Pg.222]

Lerman, A. Mackenzie, F.T. 2005. 0O2 air-sea exchange due to calcium carbonate and organic matter storage, and its implications for the global carbon cycle. Aquatic Geochemistry, 11, 345-390. [Pg.480]

Espana, J.S., Pamo, E.L., Pastor, E.S., Andres, J.R., Rubi, J.A.M. 2006. The removal of dissolved metals by hydroxysulfate precipitation during oxidation and neutralization of acid mine waters, Iberian Pyrite Belt. Aquatic Geochemistry, 12,269-298. [Pg.38]

JOHANNESSON, K. H., LYONS, W. B., STETZENBACH, K. J. Byrne, R. H. 1995. The solubility control of rare earth elements in natural terrestrial waters and the significance of P043- and C032-in limiting dissolved concentrations A review of recent information. Aquatic Geochemistry, 1, 157-173. [Pg.141]

Aiuppa, A., D Alessandro, W Federico, C. et al. (2003) The aquatic geochemistry of arsenic in volcanic groundwaters from southern Italy. Applied Geochemistry, 18(9), 1283-96. [Pg.199]

Xstrom, M. and Corin, N. (2000) Abundance, sources and speciation of trace elements in humus-rich streams affected by acid sulphate soils. Aquatic Geochemistry, 6(3), 367-83. [Pg.200]

Elbaz-Poulichet, F., Nagy, A. and Cserny, T. (1997) The distribution of redox sensitive elements (U, As, Sb, V and Mo) along a river-wetland-lake system (Balaton region, Hungary). Aquatic Geochemistry, 3(3), 267-82. [Pg.207]

Johannesson, K.H., Lyons, W.B., Huey, S. et al. (1997) Oxyanion concentrations in eastern Sierra Nevada rivers — 2. Arsenic and phosphate. Aquatic Geochemistry, 3(1), 61-97. [Pg.214]

Loring, D.H., Dahle, S., Naes, K. et al. (1998) Arsenic and other trace metals in sediments from the Kara Sea and the Ob and Yenisey estuaries, Russia. Aquatic Geochemistry, 4(2), 233-52. [Pg.217]

Mucci, A., Richard, L.-F., Lucotte, M. and Guignard, C. (2000) The differential geochemical behavior of arsenic and phosphorus in the water column and sediments of the Saguenay Fjord estuary, Canada. Aquatic Geochemistry, 6(3), 293-324. [Pg.220]

Morse, J. W. Mackenzie, F. T. 1998. Hadean ocean carbonate geochemistry. Aquatic Geochemistry, 4, 301-319. [Pg.256]

Millero, EJ. Pierrot, D. (1998) Aquatic Geochemistry 4, 153-199, Kluwer, Amsterdam. [Pg.315]

LIGAND SUBSTITUTION KINETICS AND COMPUTER MODELING IN AQUATIC GEOCHEMISTRY... [Pg.383]

Dyrssen, D.W. (1999) Framvaren and the Black Sea - Similarities and differences. Aquatic Geochemistry, 5, 59-73. [Pg.87]

Dyrssen, D.W., Skei, J.M., Ostlund, H.G., Hall, P.O.J., Haraldsson, C. and Chierici, M. (1996) Time dependence of organic matter decay and mixing processes in Framvaren, a permanently anoxic fjord in south Norway. Aquatic Geochemistry, 2, 111-129. [Pg.87]

Hallberg, R.O. and Larsson, C. (1999) Biochelates as a cause of metal cycling across the redoxcline. Aquatic Geochemistry, 5, 269—280. [Pg.87]

Wensheng, Y. and Millero, F.J. (1995) The chemistry of the anoxic waters in the Framvaren Fjord, Norway. Aquatic Geochemistry, 1, 53-88. [Pg.90]

Morita, A. and B. C. Garrett (2008) Molecular theory of mass transfer kinetics and dynamics at gas-water interface. Fluid Dynamics Research 40, 459-473 Moriwaki, R., Kanda, M. and H. Nitta (2006) Carbon dioxide build-up within a suburban canopy layer in winter night. Atmospheric Environment 40, 1394-1407 Morkovnik, A. F. and O. Yu. Okhlobystin (1979) Inorganic radical-ions and their organic reactions. Russian Chemical Review 40, 1055—1075 Morse, J. W., and F. T. MacKenzie (1998) Hadean ocean carbonate chemistry. Aquatic Geochemistry 4, 301-319... [Pg.661]

Druschel, G.K., Hamers, R.I, Luthe Illr, G.W., Banfield, IF. (2003). Kinetics and mechanism of trithionate and tetrathionate oxidation at low pH by hydroxyl radicals. Aquatic Geochemistry, 9, 145-164. [Pg.214]

Charlet, L., and C. Toumassat. 2005. Fe(II)-Na(I)-Ca(II) cation exchange on montmoriUonite in chloride medium Evidence for preferential clay adsorption of chloride-metal ion pairs in seawater. Aquatic Geochemistry 11, no. 2 115-137. [Pg.155]

Liitzenkirchen, J., and Ph. Behra. 1995. On the surface precipitation model for cation sorption at the (hydr)oxide water interface. Aquatic Geochemistry 1, no. 4 375-397. doi 10.1007/ BF00702740. [Pg.444]

FIGURE 13.10 Cadmium binding by HA. The data are from Benedetti et al. (1995). Lines are fits with WHAM VI (4 adjustable parameters). (O) pH = 4 ( ) pH = 6 ( ) pH = 8. (Reprinted with kind permission from Springer Science -I- Business Media Aquatic Geochemistry, Tipping E., Humic ion-binding model VI An improved description of the interactions of protons and metal ions with humic substances, 4,1998, 3-48, Copyright 1998.). [Pg.463]

Tipping, E. 1998. Humic ion-binding model VI An improved description of the interactions of protons and metal ions with humic substances. Aquatic Geochemistry 4, no. 1 3 8. [Pg.477]

Kostirev, A. N. (2009). Kara-Bogaz-Gol Bay Physical and chemical evolution. Aquatic Geochemistry, 15, 223-236. [Pg.1547]

Zavialov, P. O. (2009b). Ongoing changes of ionic composition and dissolved gases in the Aral Sea. Aquatic Geochemistry, 15, 263-275. [Pg.1547]

ROBERT G. M. SPENCER is Assistant Scientist at the Woods Hole Research Center, Falmouth, Massachusetts. He is an Earth system scientist whose research encompasses both aquatic geochemistry and biogeochemistry, focused predominantly on the carbon and nitrogen cycles. [Pg.395]

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