Abstract
The situation that environmentally relevant species take part in chemical reactions, while being transported through a compartment of the environment, was already treated in Chap. 7. In this chapter the same situation is taken up again with the difference concerning the time scale of the reactions. Here we deal with reactions which are fast in comparison to transport processes.
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References
Berner RA (1971) Principles of chemical sedimentology. McGraw-Hill, New York, p 240
Debye P, Hückel E (1923) Zur Theorie der Elektrolyte. Physikalische Zeitschrift 23:185–206, in German
Fang Y, Yeh G-T, Burgos WD (2003) A general paradigm to model reaction-based biogeochemical processes in batch systems. Water Res Res 39(4):1083. doi:10.1029/2002WR001694
Holzbecher E (2005) Reactive transport – concepts and numerical approaches. In: Ingham DB, Pop I (eds) Transport phenomena in porous media, vol III. Elsevier, Oxford, pp 305–340
Holzbecher E (2006) On the coupling of transport and chemical speciation calculations with FEMLAB. Chem Eng Technol 29(5):5–7, Supplement ‘Trends in Chemical Engineering’
Klug M, Sanches M, Laranjeira M, Fávere V, Rodrigues C (1998) Anályse das isotermas de adsorção de Cu(II), Cd(II), Ni(II) e Zn(II) pela N-(3,4-dihidroxibenzil) quitosana empregando o método da regressão não linear. Química Nova 21(4):410–413, in Potuguese
Krauskopf KB, Bird DK (1995) Introduction to geochemistry. McGraw Hill, New York, p 647
Parkhurst DL (1995) PHREEQC: a computer program for speciation, reaction-path, advective transport, and inverse geochemical calculations, Lakewood. U.S. Geological Survey, Water Resources Investigation Report 95–4227, p 143
Saaltink MW, Ayora C, Carrera J (1998) A mathematical formulation for reactive transport that eliminates mineral concentrations. Water Res Res 34(7):1649–1656
Saaltink MW, Carrera J, Ayora C (2001) On the behavior of approaches to simulate reactive transport. J Contaminant Hydrol 48:213–235
Sigg L, Stumm W (1989) Aquatische Chemie. vdf-Verlag, Zurich, p 498, in German
Steefel CI, MacQuarrie KTB (1996) Approaches to modeling of reactive transport in porous media. In: Lichtner PC, Steefel CI, Oelkers EH (eds) Reactive transport in porous media, reviews in mineralogy, vol 34, Mineral. Soc.of Am., pp 83–129
van der Lee J (1998) Thermodynamic and mathematical concepts of CHESS, Ècole des Mines de Paris. Technical Report LHM/RD/98/39, p 99
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Holzbecher, E. (2012). Transport and Equilibrium Reactions. In: Environmental Modeling. Springer, Berlin, Heidelberg. https://doi.org/10.1007/978-3-642-22042-5_8
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DOI: https://doi.org/10.1007/978-3-642-22042-5_8
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