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Mechanism of Ni mobilization in a groundwater well field; case study from Racibórz, Poland. Konrad Miotliński, Andrzej Kowalczyk University of Silesia, Faculty of Earth Sciences, Sosnowiec, PL Lisbon, 31 October 2008. Purpose of the study.
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Mechanism of Ni mobilization in a groundwater well field; case study from Racibórz, Poland Konrad Miotliński, Andrzej Kowalczyk University of Silesia, Faculty of Earth Sciences, Sosnowiec, PL Lisbon, 31 October 2008
Purpose of the study Characteristics of factors and identification into the processes that control mobilization of Ni to groundwater in the biggest groundwater well field in Racibórz
RACIBÓRZ • 60 thousand inhabitants • 100% supplied by groundwater • Oder River • Ulga Channel
BURIED VALLEY • Main source of water provision • Pleistocene • Lenght: 10 km • Width: 2 km • Thickness of Q deposits: up to 60 m • Axis of the valley – 2 km to the W of the modern river valley A B
Hydrogeological cross-section A B Sitek i in., 2007
Well S-I Kations, meq/L Start of increase of Ni concentration Anions, meq/L
WellS-II Kations, meq/L Start of increase of Ni concentration Anions, meq/L
Water table elevation s = 20m s = 10m
1-D Reactive transport modelling(Phreeqc) S-II Fe+Mn+Ni Fe Ni*100 Concentration, mmol/L Mn*10
Ni concentration in the depth profile Content of Ni in sediment, ppm Concentration of Ni in groundwater, mmol/L Water table 94% Ni bound to oxides 6% bound to pyrite All Ni bound to pyrite Maximal admissible concentration: 0,02 mgNi/L =0,339 molNi/L
Contents of Ni in pyrite • Racibórz (Poland): • 16-54*10-5 molNi/molFeS2 (This contribution) • Aarhus (Denmark): • 40-140*10-5 molNi/molFeS2(Larsen&Postma, 1997) • Contemporary marine sediments: • 2*10-5-6*10-2 molNi/molFeS2(Huerta-Diaz&Morse, 1992)
a) b) Ni/Mn Ni/Fe Concentration Mn, mmol/L Concentration Fe, mmol/L c) Data: August 2005 Ni/pH 6,7 pH Correlations
Sorption of Ni in siliceous environment Dzombak & Morel, 1990 (synthetic Fe(OH)3(a)) Kjøller et al., 2004 Amount of adsorbed Ni, % pH range of studied water Christensen et al., 1996 pH of water Solid line – syntethetic Fe(OH)3(a); Dotted lines – natural sediment
Conceptual model of Ni mobilization Before groundwater exploitation
Conceptual model of Ni mobilization Start of exploitation (Fe(1-x), Nix)S2 + 7/2O2 + H2O → (1-x)Fe2+ + xNi2+ + 2SO42- +2H+ 5(Fe(1-x), Nix)S2 + 14NO3 + 4H+→ 7N2 + 5(1-x)Fe2+ + 5xNi2+ + 10SO42- +2H2O
Conceptual model of Ni mobilization During extensive exploitation Fe2+ + ¼ O 2 + H+→ Fe 3+ + ½H2O Fe 3+ + 3H2O → Fe(OH)3+3H+ Mn2+ + 2O2 +4H+→ MnO2+2H2O Surface complexation of Ni: SOH + Ni2+ = SONi+ +H+
Conceptual model of Ni mobilization Groundwater recovery (since 1994) • Flooding of Mn and Fe-oxides
Conceptual model of Ni mobilization At present 2Fe2+ + MnO2 + 4 H2O → 2Fe(OH)3 + Mn2++ 2H+ (wtórna mobilizacja Ni)
1-D Reactive transport modelling(Phreeqc) S-II Fe+Mn+Ni Fe Ni*100 Concentration, mmol/L Mn*10
Reduction of Mn-oxides Århus, Dania (Larsen i Postma, 1997) 20 10 m a.s.l. 0 -10
Conclusions • Pyrite – primary source of Ni • Pyrite oxidation – Ni mobilization • Sorption of Ni on solid phase – Mn- and Fe-oxidese • Flooding of Mn-oxides causes the reaction of oxides with ferrous iron, their reduction and Ni re-mobilization.