Phosphorus speciation in dicalcium silicate phases: Application to the basic oxygen furnace (BOF) slag

The recycling of basic oxygen furnace slag in the steelmaking process is currently limited by its phosphorus content. Phosphorus is known to induce remarkable phase segregation in the slag microstructure and is only present in phases belonging to the C2S–C3P solid solution, the iron-containing phase...

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Veröffentlicht in:	Cement and concrete research 2015-07, Vol.73, p.207-214
Hauptverfasser:	Duée, Cédric, Bourgel, Christine, Véron, Emmanuel, Allix, Mathieu, Fayon, Franck, Bodénan, F., Poirier, Jacques
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Sprache:	eng
Schlagworte:	Basic converters Ca2SiO4 Calcium Cement Chemical and Process Engineering Dicalcium silicate Engineering Sciences Iron and steel making Phases Phosphorus Slags Solid solutions Structural characterization Waste management
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creator	Duée, Cédric Bourgel, Christine Véron, Emmanuel Allix, Mathieu Fayon, Franck Bodénan, F. Poirier, Jacques
description	The recycling of basic oxygen furnace slag in the steelmaking process is currently limited by its phosphorus content. Phosphorus is known to induce remarkable phase segregation in the slag microstructure and is only present in phases belonging to the C2S–C3P solid solution, the iron-containing phases being left free of phosphorus. The mechanism of phosphorus insertion into calcium silicate structures was studied by a combination of TEM, XRD and 29Si and 31P solid-state NMR. Upon P2O5 addition, [PO4]3− units are incorporated into the dicalcium silicate structure by substituting [SiO4]4− groups, charge balance being maintained by creation of calcium vacancies. This substitution leads to a stabilization of the β- and α-Ca2SiO4 phases at room temperature and results in the formation of more polymerized calcium silicate secondary phases. The obtained P-substituted α-Ca2SiO4 compounds belong to the Ca2−x/2Si1−xPxO4 solid solution and exhibit lattice parameters similar to those of the calcium phosphosilicate Ca15(PO4)2(SiO4)6 phase.
doi_str_mv	10.1016/j.cemconres.2015.03.012
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Phosphorus is known to induce remarkable phase segregation in the slag microstructure and is only present in phases belonging to the C2S–C3P solid solution, the iron-containing phases being left free of phosphorus. The mechanism of phosphorus insertion into calcium silicate structures was studied by a combination of TEM, XRD and 29Si and 31P solid-state NMR. Upon P2O5 addition, [PO4]3− units are incorporated into the dicalcium silicate structure by substituting [SiO4]4− groups, charge balance being maintained by creation of calcium vacancies. This substitution leads to a stabilization of the β- and α-Ca2SiO4 phases at room temperature and results in the formation of more polymerized calcium silicate secondary phases. 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Phosphorus is known to induce remarkable phase segregation in the slag microstructure and is only present in phases belonging to the C2S–C3P solid solution, the iron-containing phases being left free of phosphorus. The mechanism of phosphorus insertion into calcium silicate structures was studied by a combination of TEM, XRD and 29Si and 31P solid-state NMR. Upon P2O5 addition, [PO4]3− units are incorporated into the dicalcium silicate structure by substituting [SiO4]4− groups, charge balance being maintained by creation of calcium vacancies. This substitution leads to a stabilization of the β- and α-Ca2SiO4 phases at room temperature and results in the formation of more polymerized calcium silicate secondary phases. 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subjects	Basic converters Ca2SiO4 Calcium Cement Chemical and Process Engineering Dicalcium silicate Engineering Sciences Iron and steel making Phases Phosphorus Slags Solid solutions Structural characterization Waste management
title	Phosphorus speciation in dicalcium silicate phases: Application to the basic oxygen furnace (BOF) slag
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