Pb 2+, Cu 2+and Cd 2+ ions uptake by Brazilian phosphate rocks

Mavropoulos, Elena; Rocha, Nilce C. C. da; Moreira, Josino C.; Bertolino, Luíz C.; Rossi, Alexandre M.

doi:10.1590/S0103-50532005000100010

Abstracts

In this work Brazilian phosphate rocks, PRs, were used to reduce Pb2+, Cu2+ and Cd2+ concentrations from aqueous solutions. We concluded that these metals were mainly immobilized by fluorapatite but other minerals such as calcium carbonate also contribute to their immobilization. In the case of lead two mechanisms are proposed: the Ca10(PO4)6F2 dissolution followed by the precipitation of (Ca,Pb)10(PO4,CO3) 6(OH,F,Cl)2.56.1.5H2O and CaCO3 dissolution with the formation of a PbCO3. The occurrence of this second mechanism improves the uptake efficiency but contribute to the increases of lead bioavailability because lead carbonate is more soluble than fluorpyromorphite. This fact could limit the use of PRs for remediation of contaminated soils and wastes. The Cu2+ and Cd2+ removal by PRs is controlled by adsorption mechanisms but dissolution /precipitation mechanisms also occur. In the case of Cu2+, fluorapatite dissolution followed by Cu2(PO4)(OH) precipitation.

lead; cadmium and cooper immobilization; phosphate rock; hydroxyapatite

Neste trabalho, rochas fosfatadas brasileiras (PRs) foram usadas na imobilização de Pb2+, Cu2+ e Cd2+ de soluções aquosas. Concluímos que estes metais são principalmente imobilizados por fluorapatita, mas outros minerais tais com carbonatos de cálcio contribuem para esta imobilização. No caso do chumbo, dois mecanismos são propostos: a dissolução da Ca10(PO4)6F2 seguida pela precipitação de (Ca,Pb)10(PO4,CO3) 6(OH,F,Cl)2.56.1.5H2O e a dissolução de CaCO3 com formação de PbCO3. Este segundo mecanismo aumenta a eficiência do processo de remoção, mas contribui para tornar o chumbo mais biodisponível porque o carbonato de chumbo é mais solúvel que a fluorpiromorfita. Este fato pode limitar a utilização das rochas fosfatadas na regeneração de solos contaminados. A imobilização de Cu2+ e do Cd2+ pelas PRs é controlada por mecanismos de adsorção mas mecanismos de dissolução/precipitação também contribuem. No caso do Cu2+ a dissolução da fluorapatita é seguida pela precipitação da libetenita, Cu2(PO4)(OH).

ARTICLE

Pb ²⁺, Cu ²⁺and Cd ²⁺ ions uptake by Brazilian phosphate rocks

Elena Mavropoulos^I; Nilce C. C. da Rocha^II; Josino C. Moreira^III; Luíz C. Bertolino^IV; Alexandre M. Rossi^* * e-mail: rossi@cbpf.br ^{, I}

^ICBPF, Rua Dr Xavier Sigaud 150, Urca, 22290-180 Rio de Janeiro - RJ, Brazil

^IIInstituto de Química, Universidade Federal do Rio de Janeiro, Cidade Universitária, C T, Bloco A/517, 21949-900 Rio de Janeiro - RJ, Brazil

^IIICESTEH/FIOCRUZ, Rua Leopoldo Bulhões 1480, 21045-900 Rio de Janeiro - RJ, Brazil

^IVDGEO/FFP, Universidade Estadual do Rio de Janeiro, Rua Francisco Portela 794, 22425-000 Rio de Janeiro - RJ, Brazil

ABSTRACT

In this work Brazilian phosphate rocks, PRs, were used to reduce Pb²⁺, Cu²⁺ and Cd²⁺concentrations from aqueous solutions. We concluded that these metals were mainly immobilized by fluorapatite but other minerals such as calcium carbonate also contribute to their immobilization. In the case of lead two mechanisms are proposed: the Ca₁₀(PO₄)₆F₂ dissolution followed by the precipitation of (Ca,Pb)₁₀(PO₄,CO₃)₆(OH,F,Cl)_2.56.1.5H₂O and CaCO₃ dissolution with the formation of a PbCO₃. The occurrence of this second mechanism improves the uptake efficiency but contribute to the increases of lead bioavailability because lead carbonate is more soluble than fluorpyromorphite. This fact could limit the use of PRs for remediation of contaminated soils and wastes. The Cu²⁺ and Cd²⁺ removal by PRs is controlled by adsorption mechanisms but dissolution /precipitation mechanisms also occur. In the case of Cu²⁺, fluorapatite dissolution followed by Cu₂(PO₄)(OH) precipitation.

Keywords: lead, cadmium and cooper immobilization, phosphate rock, hydroxyapatite

RESUMO

Neste trabalho, rochas fosfatadas brasileiras (PRs) foram usadas na imobilização de Pb²⁺, Cu²⁺ e Cd²⁺ de soluções aquosas. Concluímos que estes metais são principalmente imobilizados por fluorapatita, mas outros minerais tais com carbonatos de cálcio contribuem para esta imobilização. No caso do chumbo, dois mecanismos são propostos: a dissolução da Ca₁₀(PO₄)₆F₂ seguida pela precipitação de (Ca,Pb)₁₀(PO₄,CO₃)₆(OH,F,Cl)_2.56.1.5H₂O e a dissolução de CaCO₃ com formação de PbCO₃. Este segundo mecanismo aumenta a eficiência do processo de remoção, mas contribui para tornar o chumbo mais biodisponível porque o carbonato de chumbo é mais solúvel que a fluorpiromorfita. Este fato pode limitar a utilização das rochas fosfatadas na regeneração de solos contaminados. A imobilização de Cu²⁺ e do Cd²⁺ pelas PRs é controlada por mecanismos de adsorção mas mecanismos de dissolução/precipitação também contribuem. No caso do Cu²⁺a dissolução da fluorapatita é seguida pela precipitação da libetenita, Cu₂(PO₄)(OH).

Introduction

The increasing rate of the environment pollution has stimulated worldwide research concerning new materials capable to remove heavy metals from contaminated soils and wastes. Several studies have shown that synthetic hydroxyapatite, HA, have potential for remediation applications because it can immobilize a great number of heavy metals ^1-3 from aqueous media by forming new low soluble phosphates phases. However, the use of synthetic HA in technological applications is only feasible when a small quantity of material is used because HA preparation is rather expensive. For this reason, low cost materials like phosphate rocks, PRs, have been proposed and tested for heavy metal removal from contaminated waste and soils.^4,5 When the remediation properties of PR are investigated some questions are normally discussed. Could PRs be efficient enough to immobilize heavy metals as synthetic HA is? Is metal immobilization dependent on the PR mineralogical and chemical composition? Do apatite minerals always control the mechanism of metal immobilization?

Several authors made relevant contributions to this discussion showing that PR was very effective in retaining Pb and less effective in the removal Cd and Zn from aqueous solutions.⁶ The Pb²⁺ immobilization was mainly controlled by apatite dissolution and the precipitation of a carbonated fluoropyromorphite.^7,8Recently, in situ studies have been conducted with success.⁸¹² However, the use of PRs in remediation of soils and wastes does not only depend on the effectiveness of the removal process but mainly on the stability of the new metal phases formed. A high bioavailability of this new metal phase could limit the use of PRs in situ applications.

In this work, we showed that depending on PRs composition, other minerals might compete with apatite for metal removal. For this, we investigate the effectiveness of PRs samples from the southeast (São Paulo and Minas Gerais States) central west and northeast (Goiás and Bahia States) of Brazil in attenuating Pb²⁺, Cu²⁺ and Cd²⁺ from aqueous solution. A comparative study concerning the immobilization process of PR and synthetic apatite was also performed. The uptake experiments were carried out with different grain size fractions of PR in order to identify the minerals that participate in the Pb²⁺, Cu²⁺ and Cd²⁺ removal. Discussion about the uptake mechanisms of Pb²⁺, Cu²⁺ and Cd²⁺ by Brazilian PRs and their potential for remediation applications was carried out.

Experimental

Sample preparation

Five PRs from different Brazilian regions were studied. PRA sample was collected in a Cretaceous igneous-alkaline deposit situated in Tapira region, Minas Gerais State. The PRB and PRE samples belong to an igneous-alkaline complex of Cretaceous Superior from Goias State.¹³ The PRD and PRC samples came from Bahia and Minas Gerais States deposits, respectively. They are from Medium and Superior Proterozoic and have sedimentary origins. The PRs samples were obtained in form of a heterogeneous powder of coarse particles. Samples were homogenized in agate grail and separated in six grain fractions: PR₁ (<0.074 mm), PR₂ (0.074-0.125 mm), PR₃ (0.125-0.177 mm) PR₄ (0.177-0.210 mm), PR₅ (0.210-0.250 mm) and PR₆ (0.250-2.00 mm). Their BET surface areas were 16.1, 13.7, 11.4, 9.2, 4.6 and 8.7 m² g^-1, respectively.

Synthetic hydroxyapatite (HA) samples were synthesized by drop wise addition of an (NH₄)₂HPO₄ aqueous solution to a Ca(NO₃)₂ solution (both reagents PA Merck) at 80 ºC and pH 11. It was a pure HA with a Ca/P molar ratio of 1.65 ± 0.03 and surface area BET of 45 ± 4 m² g^-1.

Sample characterization

The PRs and HA samples were analyzed by a SEIFERT-FPM GmbH X-ray diffractometer (XRD), operating with CuKa radiation (1.5418 Å) at 40 kV and 40 mA with a graphite monochromator in the primary bunch. The XRD patterns were obtained in an interval from 10 to 100º with 2q step of 0.02º. The apatite and calcite crystallite mean sizes were determined using Scherer equation. Elementary chemical analysis of Ca and P content and other elements were determined by ICP-OES using equipment OPTIMA 3000 PERKIN-ELMER. Sample thin section were prepared and analyzed with polarizing microscope Carl Zeiss Axioplan.

Dissolution experiments

Dissolution experiments in Milli-Q water were accomplished in triplicate, using 0.2 g of synthetic HA, PRA and PRA₁ samples. They were mechanically shaken in 40 mL tubes during 10 days. After 4, 24, 48, 72, 168 and 240 hours solution aliquots were collected, filtered using a 0.22 mm Durapore membrane Millipore and diluted in HNO₃0.25%. The Ca and P content were then determined by ICP-OES. The pH was monitored during HA, PR and PR finest fractions (PR₁) dissolution in Milli-Q water using a calibrated pH meter Analyser-300 M.

Uptake, desorption and pH experiments

The uptake experiments using HA, PRA and its fractions (PRA_i) were performed in triplicate using 0.2 g of each sample. Aqueous solutions (40 mL) containing Pb²⁺ (2.43´10^-3 mol L^-1), Cu²⁺ (5.16´10^-3 mol L^-1) and Cd²⁺ (2.67´10^-3 mol L^-1), obtained from Pb(NO₃)₂, Cu(NO₃)₂.3H₂O and Cd(NO₃)₂.4H₂O, were mechanically shaken up to 10 days. The sample suspensions were centrifuged and the supernatants were filtered using a 0.22 mm membrane Millipore, diluted with HNO₃ 0.25% and then analyzed by ICP. The solid residues were dried at 80 ºC and analyzed by XRD. The same procedure was used in a second series of experiments in order to evaluate the uptake capacity of Pb²⁺, Cu²⁺ and Cd²⁺ by HA and PRA. These 240 hours experiments used Pb²⁺, Cu²⁺ and Cd²⁺initial concentrations of 0.94-1.50´10^-3 mol L^-1, 0.71-4.33´10^-3 mol L^-1 and 0.91-2.36´10^-3 mol L^-1, respectively.

A third series of experiments was performed to estimate the uptake effectiveness of each one of the PRs (PRA, PRB, PRC, PRD and PRE) and their finest fractions (PRA₁, PRB₁, PRC₁, PRD₁ and PRE₁). Solutions containing Pb²⁺ 1.46´10^-3 mol L^-1, Cu²⁺ 0.85´10^-3 mol L^-1and Cd²⁺ 0.78´10^-3 mol L^-1 were used in these 3 days experiments. The sample suspensions and the solid residues were treated and analyzed by ICP and XRD as described before.

The metal selectivity along the uptake process was investigated by the following procedure: 0.2 g of HA, PRA and PRA₁ were added to 40 mL of an aqueous solutions containing nearly 1´10^-3 mol L^-1of Pb²⁺, Cu²⁺ and Cd²⁺. Supernatants aliquots were withdrawn from solution after 72 hours of reaction and analyzed by ICP. The availability of Pb²⁺, Cu²⁺ and Cd²⁺ by PR was also investigated: after uptake, the sample was washed in Milli-Q water and centrifuged. The solid was added to 40 mL of Milli-Q water and maintained under agitation during 7 days. Afterwards, the solutions were separated from solid and analyzed by ICP. The pH was monitored during the uptake experiments as described before.

Results and Discussion

Mineralogical and structural characterization

Thin section analyses showed that PRs were composed by apatite, mica, goethite, magnetite, calcite and quartz. The most abundant elements of PRs were Ca, P, Fe and Al but other metals like Cr, Ni, Zn, Pb, Cu and Cd were also presented in small amounts (Table 1). Ca and P contents were highly variable among the studied samples. Morphological characterization revealed that PR had a threemodal particle size distribution with maximum centered at 130, 36 and 4 mm while synthetic HA had a bimodal particle size distribution with maximum centered at 4 and 23 mm. Particles with dimensions around 4 mm were mainly presented in synthetic HA but contributed weakly in the PRA and PRA₁ fractions.

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Differently from others PRs already studied ^6-8 the Brazilian PRs were mainly composed by fluorapatite, Ca₁₀(PO₄)₆F. In one sample a small substitution of F^- by OH^-and PO₄^3- by CO₃^2-was observed by XRD. No other phosphate was detected by XRD. Quartz peaks were detected in all XRD patterns with relative intensities varying in the following order: PRE>PRA>PRD>PRC>PRB. Peaks of calcite were identified in the PRB and PRD samples. Among PR₁ fractions, calcite peaks were mainly concentrated in samples PRA₁ and PRD₁ as ultra fine particles with mean crystal size of 64 nm.

The fluorapatite relative content of PRs was estimated by XRD by comparing peaks intensity at 2q = 31.94 (100%), 2q = 32.26 (55%) and 2q = 33.11 (60%). In samples PRB and PRA, fluorapatite was mainly concentrated in the large and small particle size fractions, respectively. It was homogeneously distributed between raw and fine fractions in sample PRC, PRD and PRE. The XRD analysis revealed that fluorapatite crystals had larger crystallite dimensions (50 nm along 002 direction) and lower specific surface areas than synthetic HA. This improvement on PR crystallinity and crystallite dimension was probably due to thermal treatments submitted by PR during their geological genesis.

Dissolution of PR and pH behavior during metal uptake

Dissolution rate and pH are important parameters to understand the mechanism and effectiveness of heavy metals removal by PRs in water solutions.^9,11,14,15 In the present work, dissolution experiments showed that dissolution rate was strongly variable among PRs samples but was not directly related to sample Ca or P contents. The variations were more pronounced in respect to the amount of Ca released to the solution than to P, due to the existence of more soluble Ca-compounds such as CaCO₃in some of the PRs like samples PRA and PRD. Dissolution experiments in Milli-Q water using samples PRA and PRA₁ showed that the equilibrium of Ca and P was no longer achieved even for dissolution times up to 240 hours (data not shown). The dissolution Ca/P ratio for PRA (Ca/P=11.50) and PRA₁ (Ca/P=10.30) was higher than that of HA (Ca/P=0.39), which should be due to the contribution of other Ca-compounds existing in PR beside apatite. This explains why PRA₁ released twice more Ca²⁺ than synthetic HA but was less efficient in releasing P. Dissolution data also revealed that the release of Ca and P was mostly originated from sample fine fractions, which were rich in apatite and carbonate minerals.

The pH increased rapidly when PRs were dissolved in Milli-Q water due to the presence of basic minerals (Table 2). It varied from 6.2 to 9.2 and reached its highest values for PRA₁ and PRD₁ samples, which had the highest calcite contents. In the beginning of the Pb²⁺, Cu²⁺ or Cd²⁺ immobilization by HA, Table 3, the pH decreased indicating that metal complexation at HA surface ² was so efficient as apatite dissolution.^16,17 The same behavior was only seen in the beginning of Pb²⁺ immobilization by PRA. For Cu²⁺ and Cd²⁺ immobilization by PRA and PRA₁ the pH increased continuously indicating that the decrease of pH due to metal complexation was neutralized by carbonate minerals dissolution, as was observed in dissolution experiments (Table 2).

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Uptake and desorption experiments

Sorption experiments using PRA sample showed (Figure 1 and Table 4), that the removal of Pb²⁺, Cu²⁺ and Cd²⁺ was dependent on metal initial concentration and the uptake time. The Pb²⁺uptake was 30% lower than synthetic HA in the first 4 hours of the kinetic process but achieved 90% at the end of 72 hours (Table 4). It increased with the decrease of PR grain size (Figure 2), and the highest immobilization occurs for R₁ fraction, which was rich in fluorapatite.

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The Pb²⁺ immobilization by PRs, Figure 3, was strongly variable and decreased in the following order: PRA>PRB>PRE>PRD>PRC. The uptake effectiveness of raw samples and their fine fractions varied from 5 mg g^-1 (PRC) to 36 mg g^-1 (PRA) and from 6 mg g^-1 (PRC₁) to 57 mg g^-1 (PRA₁), respectively. These variations could not be attributed to sample Ca or P contents or to sample surface area because samples PRB₁ and PRA₁ had similar BET areas but PRA₁immobilized 2.5 times more Pb than PRB₁. In addition, PRA sample had smaller Ca and P contents than the PRC sample but immobilized about 7 times more Pb. Figure 3 also revealed that the removal efficiency was not influenced by sample geological origin: samples PRD and PRE showed similar Pb²⁺ uptake effectiveness but had sedimentary and igneous origins, respectively. The data of Figure 3 confirmed that Pb²⁺is mainly immobilized by PRs fine fractions and also suggested a correlation between the dissolution of Ca-compounds and the Pb²⁺ removal from aqueous solution. However, the Pb²⁺ removal was not directly related to fluorapatite content of PR: PRC₁ showed a similar fluorapatite content as PRA₁ but immobilized 9 times less Pb²⁺. This supports the proposal that other soluble Ca-compounds besides fluorapatite should also play a relevant role in Pb immobilization by PRs.

Comparing results of Table 2 and Figure 3 we verified that the high effectiveness of PR in removing Pb²⁺ was not linked to the low pH levels of the solution. Two cases exemplified this hypothesis: the PRA₁ and PRD₁ samples showed the highest Pb²⁺ uptake whereas pH was kept in high levels during the uptake process (Table 3). These results, which are in opposition to previous works,^1,3,14 can be understood by the role of other minerals of PRs during the uptake process.

The comparison between the XRD patterns of PR samples, before and after Pb²⁺ uptake, was essential to clarify the previous results as well as to detail the mechanisms of Pb²⁺ immobilization. One example was the XRD pattern of sample PRA₁ after the Pb²⁺ uptake. It showed an additional peak at 2q = 30.91 and a modification in the relative intensity of the fluorapatite peaks at 2q = 31.94, 2q = 32.26 and 2q = 33.11 in relation to non-treated sample. This changes was attributed to the formation of a solid solution of Ca and Pb such as (Ca,Pb)₁₀(PO₄,CO₃)₆(OH,F,Cl)_2.56.1.5H₂O.¹⁶ In addition to this fluorapatite solid solution, the XRD patterns of the PRA and PRD samples also showed two intense peaks at 2q = 24.83 and 2q = 25.53, which were assigned to a cerussite phase, PbCO₃.

These above results indicated that Pb²⁺ uptake by PRs involves not only one but two mechanisms: the dissolution of fluorapatite and calcite followed by precipitation of a Ca and Pb apatite solid solution and cerussite. The occurrence of these simultaneous reactions should have relevant consequences to lead immobilization by PRs. The first consequence was that calcium carbonate rich PRs samples should leads to high Pb²⁺ uptake levels. This hypothesis is confirmed by results of Figure 3, which showed that carbonate rich samples PRA₁ and PRD₁ immobilized much more lead (32-57 mg g¹) than low carbonate content ones (5-17 mg g¹). The second consequence was that lead bioavailability should increase in these samples because lead carbonate minerals are more soluble than lead apatite. This may constitute an important limitation for PRs when used in soil and wastes remediation. Hence, additional studies must to be done to estimate the release of lead from lead carbonate in complex systems like soils during long-term experiments.

For low metal concentration (<1x10^-3 mol L^-1) and reaction time of 4 hours, Cu²⁺ presented uptake effectiveness as higher as Pb (Table 4). The Cu²⁺ uptake effectiveness was ordered as HA>PRA>PRB>PRE>PRD>PRC (Figure 3), and increased with the decrease of PR grain size, achieving a maximum for PRA₁ fraction (Figure 2 and 3). This reinforced the hypothesis that apatite minerals primarily immobilized Cu²⁺. XRD analysis performed in synthetic HA samples after several days of Cu²⁺ uptake showed a reduction of HA peaks intensity and the appearance of peaks attributed to libethenite, Cu₂(PO₄)(OH) (Figure 4). This indicated that dissolution/precipitation mechanisms are also involved in Cu²⁺ immobilization besides metal adsorption in apatite surface.

The Cd²⁺ uptake was fast but achieved saturation in the first 4 hours of reaction (Figure 1). For initial concentration of nearly 1x10^-3 mol L^-1, the Cd²⁺ uptake by PRA was about 50% less effective than Pb²⁺ and Cu²⁺ (Table 4). The fine fraction was not the most efficient for the Cd²⁺ immobilization (Figure 2), contrasting with its behavior during the Pb²⁺ and Cu²⁺ uptake. This suggested that apatite minerals did not control Cd²⁺ uptake. The XRD analyses performed in PR samples after the Cd²⁺ uptake did not show peaks of new Cd phases such as Cd-apatite or Cd-carbonate. On the other hand, the Cd²⁺ uptake was not linked to the dissolution of Ca²⁺ complexes, as shown in Figure 3. Both results supported the proposal that Cd²⁺ uptake was not dependent on dissolution/precipitation mechanisms as in the case of Pb²⁺and Cu²⁺. As a consequence, adsorption mechanisms like surface complexation or ionic exchange ^2,17-20 should control Cd²⁺ immobilization. The behavior of Cd²⁺ in desortion experiments reinforced this hypothesis because PRs were more efficient in release Cd²⁺ to solution (7%) than Pb²⁺ and Cu²⁺ (2%).

Selectivity uptake experiments were carried out with Pb²⁺, Cu²⁺and Cd²⁺ simultaneously present in a solution containing synthetic HA. As shown in Table 5, the Pb²⁺ uptake by HA was not altered by the presence of the other metals in the solution. In contrast, Cu²⁺ and Cd²⁺ removal capacity decreased by 22% and 59% respectively. When PRA fraction was used in a similar experiment the Pb²⁺, Cu²⁺ and Cd²⁺ uptake presented a decrease of about 25%, 60% and 75% respectively in comparison to isolate metal uptake (Table 5). These results suggest that PR uptake effectiveness could be strongly affected when Pb²⁺, Cu²⁺ and Cd²⁺ are in contact with a more complex media.

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Conclusions

From the above results we can conclude that Brazilian PR had high efficiency in immobilizing Pb²⁺, Cu²⁺ and Cd²⁺ from aqueous media. The existence of an ultra fine fraction of calcium carbonate in some of PRs contributed to improve their efficiency in removing Pb²⁺ because the uptake was not only exclusively controlled by the Ca-apatite dissolution and Pb-apatite precipitation but also by the calcium carbonate dissolution and the precipitation of lead carbonate. Cu²⁺was also immobilized by mechanisms such as dissolution/precipitation with the formation of libethenite. Other minerals contribute to Cd²⁺ immobilization besides fluorapatite. These results indicated that soluble minerals containing in PR composition compete with apatite in metal immobilization processes. This could be an important limitation for using PRs in situ remediation.

Acknowledgements

The authors wish to thank CNPq, Centro de Pesquisas e Desenvolvimento Leopoldo A. M. de Mello da Petrobras and EMBRAPA/SOLOS for financial add and sample characterization.

Received: October 10, 2003

Published on the web: December 16, 2004

1. Ma, Q. Y.; Traina, S.J; Logan, T. J.; Ryan, J. A.; Environ. Sci. Technol. 1993, 27, 1803.
2. Xu, Y.; Schwartz, F. W.; Traina, S. J.; Environ. Sci. Technol 1994, 28, 1472.
3. Xu, Y.; Schwartz, F. W.; J. Contam. Hydrol. 1994, 15, 187.
4. Laperche, V.; Logan, T. J.; Gaddam, P.; Traina, S. J.; Environ. Sci. Technol 1997, 31, 2745.
5. Reichert, J.; Binner, J. G. P.; J. Mater. Sci. 1996, 31, 1231.
6. Chen, X.; Wright, J. V.; Conca, J. L.; Peurrung, L. M.; Water Air Soil Pollut 1997, 98, 57.
7. Ma, L. Q.; Rao, G. N.; Water Air Soil Pollut 1999, 110, 01.
8. Ma, Q. Y.; Logan, T. J.; Traina, S. J.; Environ. Sci. Technol 1995, 29, 1118.
9. Cao, R. X.; Ma, L. Q.; Chen, M.; Singh, S. P.; Harris, W. G.; Environ. Pollution 2003, 122, 19.
10. Chen, M.; Ma, L. Q.; Singh P. S.; Cao, R. X.; Melamed, R.; Adv. Environ. Res. 2003, 8, 93.
11. Cao, X.; Ma, L. Q.; Chen, M.; Singh, S. P.; Harris, W. G.; Environ. Sci Technol 2002, 36, 5296.
12. Melaned, R.; Cao, X.; Chen, M.; Ma, Q. L.; Sci. Total Environ 2003, 305, 117.
13. Melo, M. T. V. Depósitos de Fosfato, Titânio e Nióbio de Tapira, Minas Gerais; Departamento Nacional da Produção Mineral. Principais Depósitos Minerais do Brasil; Rochas e Minerais Industriais, vol IV, Co-edição DNPM/CPRM: Brasília, 1997, p. 41-56.
14. Chen, X., J. V. Wright, J. L. Conca; Peurrung, L. M.; Environ. Sci Technol 1997, 31, 624.
15. Zhang, P; Ryan, J. A.; Yang, J.; Environ. Sci. Technol 1998, 32, 2763.
16. Mavropoulos, E.; Rossi, A. M., Costa, A. M.; Perez, C. A. C.; Moreira, J. C.; Saldanha, M.; Environ. Sci. Technol. 2002, 36, 1625.
17. Rocha, N. C. C.; Campos, R. C. C.; Rossi, A. M., Moreira, E. L.; Barbosa, A. F.; Moure, G. T.; Environ. Sci. Technol. 2002, 36, 1625.
18. Xu, Y.; PhD. Thesis, The Ohio State University, USA, 1994.
19. Jeanjean, J.; Fedoroff, M.; Faverjon, F.; Vincent, U.; J. Mater. Sci 1996, 31, 6156.
20. Toulhoat, N.; Potocek, V.; Neskovic, C.; Radiochim. Acta 1996, 74, 257.

*

e-mail:

rossi@cbpf.br

Publication Dates

Publication in this collection
22 Mar 2005
Date of issue
Feb 2005

History

Accepted
16 Dec 2004
Received
10 Oct 2003

This work is licensed under a Creative Commons Attribution-NonCommercial 4.0 International License.

[1] 1. Ma, Q. Y.; Traina, S.J; Logan, T. J.; Ryan, J. A.; Environ. Sci. Technol. 1993, 27, 1803.

[2] 2. Xu, Y.; Schwartz, F. W.; Traina, S. J.; Environ. Sci. Technol 1994, 28, 1472.

[3] 3. Xu, Y.; Schwartz, F. W.; J. Contam. Hydrol. 1994, 15, 187.

[4] 4. Laperche, V.; Logan, T. J.; Gaddam, P.; Traina, S. J.; Environ. Sci. Technol 1997, 31, 2745.

[5] 5. Reichert, J.; Binner, J. G. P.; J. Mater. Sci. 1996, 31, 1231.

[6] 6. Chen, X.; Wright, J. V.; Conca, J. L.; Peurrung, L. M.; Water Air Soil Pollut 1997, 98, 57.

[7] 7. Ma, L. Q.; Rao, G. N.; Water Air Soil Pollut 1999, 110, 01.

[8] 8. Ma, Q. Y.; Logan, T. J.; Traina, S. J.; Environ. Sci. Technol 1995, 29, 1118.

[9] 9. Cao, R. X.; Ma, L. Q.; Chen, M.; Singh, S. P.; Harris, W. G.; Environ. Pollution 2003, 122, 19.

[10] 10. Chen, M.; Ma, L. Q.; Singh P. S.; Cao, R. X.; Melamed, R.; Adv. Environ. Res. 2003, 8, 93.

[11] 11. Cao, X.; Ma, L. Q.; Chen, M.; Singh, S. P.; Harris, W. G.; Environ. Sci Technol 2002, 36, 5296.

[12] 12. Melaned, R.; Cao, X.; Chen, M.; Ma, Q. L.; Sci. Total Environ 2003, 305, 117.

[13] 13. Melo, M. T. V. Depósitos de Fosfato, Titânio e Nióbio de Tapira, Minas Gerais; Departamento Nacional da Produção Mineral. Principais Depósitos Minerais do Brasil; Rochas e Minerais Industriais, vol IV, Co-edição DNPM/CPRM: Brasília, 1997, p. 41-56.

[14] 14. Chen, X., J. V. Wright, J. L. Conca; Peurrung, L. M.; Environ. Sci Technol 1997, 31, 624.

[15] 15. Zhang, P; Ryan, J. A.; Yang, J.; Environ. Sci. Technol 1998, 32, 2763.

[16] 16. Mavropoulos, E.; Rossi, A. M., Costa, A. M.; Perez, C. A. C.; Moreira, J. C.; Saldanha, M.; Environ. Sci. Technol. 2002, 36, 1625.

[17] 17. Rocha, N. C. C.; Campos, R. C. C.; Rossi, A. M., Moreira, E. L.; Barbosa, A. F.; Moure, G. T.; Environ. Sci. Technol. 2002, 36, 1625.

[18] 18. Xu, Y.; PhD. Thesis, The Ohio State University, USA, 1994.

[19] 19. Jeanjean, J.; Fedoroff, M.; Faverjon, F.; Vincent, U.; J. Mater. Sci 1996, 31, 6156.

[20] 20. Toulhoat, N.; Potocek, V.; Neskovic, C.; Radiochim. Acta 1996, 74, 257.

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Pb 2+, Cu 2+and Cd 2+ ions uptake by Brazilian phosphate rocks

Abstracts

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