Synthesis of novel composite sorbents based on titanium, calcium and magnesium phosphates

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Resumo

Heterogonous and mechanochemical synthesis of new materials based on titanium, calcium and magnesium phosphates have been developed for the first time. Final products demonstrate high sorption efficiency towards heavy metal cations and radionuclides. The combined action of the components ensures high sorption capacity towards different cations within a wide pH range. The optimal conditions of the processes providing the obtaining of composite products with given phase composition have been established. Using solid precursors and phosphorus-containing agents taken in a stoichiometric ratio, and mild hydrothermal conditions make it possible to reduce liquid waste to a minimum level. During the first step of synthesis both precipitation of titanium phosphate and formation of ammonium phosphate which is the precursor for the second step occur. The latter is the formation of calcium and magnesium phosphates. Thus, the synthesis proceeds in accordance with the principles of green chemistry.

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Sobre autores

N. Mudruk

Tananaev Institute of Chemistry – Subdivision of the Federal Research Centre “Kola Science Centre of the Russian Academy of Sciences” Science Centre of the Russian Academy of Sciences (ICT KSC RAS)

Autor responsável pela correspondência
Email: n.mudruk@ksc.ru
Rússia, 184209 Apatity

M. Maslova

Tananaev Institute of Chemistry – Subdivision of the Federal Research Centre “Kola Science Centre of the Russian Academy of Sciences” Science Centre of the Russian Academy of Sciences (ICT KSC RAS)

Email: n.mudruk@ksc.ru
Rússia, 184209 Apatity

A. Nikolaev

Tananaev Institute of Chemistry – Subdivision of the Federal Research Centre “Kola Science Centre of the Russian Academy of Sciences” Science Centre of the Russian Academy of Sciences (ICT KSC RAS)

Email: n.mudruk@ksc.ru

Corresponding Member of the RAS

Rússia, 184209 Apatity

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2. Fig. 1. Diffractograms of samples of titanium phosphates TR: dried at 60 °C (1), calcined at 850 °C (2).

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3. Fig. 2. Diffractograms of samples of Ca–Mg CMR phosphates dried at 60 °C: after treatment with a 10% solution H3PO4 (1), after treatment with 1M NH4H2PO4 (2) solution.

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4. Fig. 3. Diffractograms of Ti composite phosphate– Ca–Mg TSMR: dried at 60 °C (1), calcined at 850 °C (2).

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5. Fig. 4. Diffractogram of a composite phosphate product obtained as a result of mechanochemical synthesis.

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6. Fig. 5. The sorption efficiency of Cs+, Sr2+ and Co2+ on the obtained samples of Ti (1) phosphate, Ca–Mg (2) phosphate, Ti-Ca–Mg (3) composite phosphate at pH 2 (a) and pH 7 (b).

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7. Fig. 6. Sorption capacities of the obtained samples of Ti phosphate (1), Ca–Mg phosphate (2), Ti–Ca–Mg composite phosphate (3).

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