TY - JOUR
T1 - Interaction of aqueous Zn(II) with hematite nanoparticles and microparticles. Part 1. EXAFS study of Zn(II) adsorption and precipitation
AU - Ha, Juyoung
AU - Trainor, Thomas P.
AU - Farges, Francois
AU - Brown, Gordon E.
PY - 2009/5/19
Y1 - 2009/5/19
N2 - Sorption of Zn(II)( aq) on hematite (α-Fe 2O 3) nanoparticles (average diameter 10.5 nm) and microparticles (average diameter 550 nm) has been examined over a range of total Zn(II)( aq) concentrations (0.4-7.6 mM) using Zn K-edge EXAFS spectroscopy and selective chemical extractions. When ZnCl 2 aqueous solutions were reacted with hematite nanoparticles (HN) at pH 5.5, Zn(II) formed a mixture of four- and six-coordinated surface complexes [Zn(O,OH) 4 and Zn(O,OH) 6] with an average Zn-O distance of 2.04 ( 0.02 A at low sorption densities (r ≤ 1.1 /anol/m 2). On the basis of EXAFS-derived Zn-Fe 3+ distances of (3.10-3.12) ± 0.02 Å, we conclude that both Zn(O,OH) 6 and Zn(O,OH)4 adsorb on octahedral Fe 3+ (O,OH) 6 or pentahedral Fe 3+ (O,OH) 5 surface sites on HN as inner-sphere, mononuclear, bidentate, edge-sharing adsorption complexes at these low sorption densities. It is possible that polynuclear Zn complexes are also present because of the similarity of Zn and Fe backscattering. At higher Zn(II) sorption densities on hematite nanoparticles (r ≥ 3.38 μmol/m 2), we observed the formation of Zn(O,OH) 6 surface complexes, with an average Zn-O distance of 2.09 ( 0.02 Å,aZn-Zn distance of 3.16 ± 0.02 Å, and a linear multiple-scattering feature at 6.12 ± 0.06 Å. Formation of a Zn(OH) 2(am) precipitate for the higher sorption density samples (r ≥ 3.38 μmol/m 2)is suggested on the basis of comparison of the EXAFS spectra of the sorption samples with that of synthetic Zn(OH) 2(am). In contrast, EXAFS spectra of Zn(II) sorbed on hematite microparticles (HM) under similar experimental conditions showed no evidence of surface precipitates even at the same total [Zn(II)( aq)] that resulted in precipitate formation in the nanoparticle system. Instead, Zn(O,OH) 6 octahedra (d(Zn-O) = 2.10 ± 0.02 Å) were found to sorb dominantly in an inner-sphere, bidentate, edge-sharing fashion on Fe 3+(O,OH) 6 octahedra at hematite microparticle surfaces, based on an EXAFS-derived Zn-Fe 3+ distance of 3.44 ± 0.02 Å. CaCl 2 selective extraction experiments showed that 10-15% of the sorbed Zn(II) was released from Zn/HN sorption samples, and about 40% was released from a Zn/HM sorption sample. These fractions of Zn(II) are interpreted as weakly bound, outer-sphere adsorption complexes. The combined EXAFS and selective chemical extraction results indicate that (1) both Zn(O,OH)4 and Zn(O,OH) 6 adsorption complexes are present in the Zn/HN system, whereas dominantly Zn(O,OH) 6 adsorption complexes are present in the Zn/HM system; (2) a higher proportion of outer-sphere Zn(II) surface complexes is present in the Zn/HM system; and (3) Zn-containing precipitates similar to Zn(OH) 2(am) form in the nanoparticle system but not in the microparticle system, suggesting a difference in reactivity of the hematite nanoparticles vs microparticles with respect to Zn(II)( aq).
AB - Sorption of Zn(II)( aq) on hematite (α-Fe 2O 3) nanoparticles (average diameter 10.5 nm) and microparticles (average diameter 550 nm) has been examined over a range of total Zn(II)( aq) concentrations (0.4-7.6 mM) using Zn K-edge EXAFS spectroscopy and selective chemical extractions. When ZnCl 2 aqueous solutions were reacted with hematite nanoparticles (HN) at pH 5.5, Zn(II) formed a mixture of four- and six-coordinated surface complexes [Zn(O,OH) 4 and Zn(O,OH) 6] with an average Zn-O distance of 2.04 ( 0.02 A at low sorption densities (r ≤ 1.1 /anol/m 2). On the basis of EXAFS-derived Zn-Fe 3+ distances of (3.10-3.12) ± 0.02 Å, we conclude that both Zn(O,OH) 6 and Zn(O,OH)4 adsorb on octahedral Fe 3+ (O,OH) 6 or pentahedral Fe 3+ (O,OH) 5 surface sites on HN as inner-sphere, mononuclear, bidentate, edge-sharing adsorption complexes at these low sorption densities. It is possible that polynuclear Zn complexes are also present because of the similarity of Zn and Fe backscattering. At higher Zn(II) sorption densities on hematite nanoparticles (r ≥ 3.38 μmol/m 2), we observed the formation of Zn(O,OH) 6 surface complexes, with an average Zn-O distance of 2.09 ( 0.02 Å,aZn-Zn distance of 3.16 ± 0.02 Å, and a linear multiple-scattering feature at 6.12 ± 0.06 Å. Formation of a Zn(OH) 2(am) precipitate for the higher sorption density samples (r ≥ 3.38 μmol/m 2)is suggested on the basis of comparison of the EXAFS spectra of the sorption samples with that of synthetic Zn(OH) 2(am). In contrast, EXAFS spectra of Zn(II) sorbed on hematite microparticles (HM) under similar experimental conditions showed no evidence of surface precipitates even at the same total [Zn(II)( aq)] that resulted in precipitate formation in the nanoparticle system. Instead, Zn(O,OH) 6 octahedra (d(Zn-O) = 2.10 ± 0.02 Å) were found to sorb dominantly in an inner-sphere, bidentate, edge-sharing fashion on Fe 3+(O,OH) 6 octahedra at hematite microparticle surfaces, based on an EXAFS-derived Zn-Fe 3+ distance of 3.44 ± 0.02 Å. CaCl 2 selective extraction experiments showed that 10-15% of the sorbed Zn(II) was released from Zn/HN sorption samples, and about 40% was released from a Zn/HM sorption sample. These fractions of Zn(II) are interpreted as weakly bound, outer-sphere adsorption complexes. The combined EXAFS and selective chemical extraction results indicate that (1) both Zn(O,OH)4 and Zn(O,OH) 6 adsorption complexes are present in the Zn/HN system, whereas dominantly Zn(O,OH) 6 adsorption complexes are present in the Zn/HM system; (2) a higher proportion of outer-sphere Zn(II) surface complexes is present in the Zn/HM system; and (3) Zn-containing precipitates similar to Zn(OH) 2(am) form in the nanoparticle system but not in the microparticle system, suggesting a difference in reactivity of the hematite nanoparticles vs microparticles with respect to Zn(II)( aq).
UR - http://www.scopus.com/inward/record.url?scp=66249132342&partnerID=8YFLogxK
U2 - 10.1021/la8028947
DO - 10.1021/la8028947
M3 - Article
AN - SCOPUS:66249132342
SN - 0743-7463
VL - 25
SP - 5574
EP - 5585
JO - Langmuir
JF - Langmuir
IS - 10
ER -