Chrysotile asbestos treated with phosphoric acid as an adsorbent for ammonia nitrogen

The purpose of this study was to find an alternative application for chrysotile asbestos, given that there is a complete structure of extraction and production of this class of serpentine minerals, but its use is banned for many applications. The idea was to obtain a compound that could immobilize p...

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Published inHeliyon Vol. 6; no. 2; p. e03397
Main Authors Girotto, Camila P., de Campos, Sílvia D., de Campos, Élvio A.
Format Journal Article
LanguageEnglish
Published England Elsevier Ltd 01.02.2020
Elsevier
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Summary:The purpose of this study was to find an alternative application for chrysotile asbestos, given that there is a complete structure of extraction and production of this class of serpentine minerals, but its use is banned for many applications. The idea was to obtain a compound that could immobilize phosphate by triggering a reaction between the magnesium oxide and hydroxide contained in the mineral, without causing phosphate leaching. To this end, chrysotile (Mg3SiO5(OH)4) was treated with phosphoric acid (H3PO4) in a molar ratio of 1:3 in an aqueous medium at 85 °C until the solvent evaporated, resulting in two different solid compounds, which were prepared in a similar manner. The first compound (cri/H3PO4 1:3)1, was obtained by rinsing and then heat-treating it at 150 °C for 6 h, while the second one, (cri/H3PO4 1:3)2, was rinsed after the heat treatment. Compound (cri/H3PO4 1:3)1 underwent partial leaching, while compound (cri/H3PO4 1:3)2 showed a mass increase of 48%, with the formation of crystalline magnesium pyrophosphate mixed with amorphous SiO2. The latter compound adsorbed N–NH3 at pH 10, following the pseudo-first-order model (activation energy = 8329 ± 1696 J mol−1). Equilibrium experiments, which were performed following Hill's sigmoidal type S2 isotherm model, indicated that the adsorption phenomenon was governed by two processes, i.e., complexation up to the inflection point (KH between 10.0 mg L−1 at 40 °C and 13.6 mg L−1 at 25 °C) followed by adsorption. The qmax varied from 18.0 to 19.6 mgN g−1 and the adsorbent was reusable, maintaining its initial adsorbent capacity during its first reuse. This material, which was tested on real effluents, presented a N–NH3 removal rate similar to that shown by the test solutions. The treatment of chrysotile with H3PO4 conducts it to a composite that adsorbs ammoniacal nitrogen at pH 10 and it is reusable maintaining the adsorption capacity. Chemical engineering; Materials chemistry, Brucite; Tridymite; N–NH3; Magnesium pyrophosphate.
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ISSN:2405-8440
2405-8440
DOI:10.1016/j.heliyon.2020.e03397