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Sodium phosphate-derived calcium phosphate cements
Calcium phosphate cements (CPC) were synthesized by the acid-base reaction between sodium phosphate, NaH2PO4 or -(-NaPO3-)-n, as the acid solution, and calcium aluminate cements (CAC) as the base reactant at 25 deg C. The extent of reactivity of -(-NaPO3-)-n with CAC was much higher than that of NaH2PO4, thereby resulting in a compressive strength of >20 MPa. Sodium calcium orthophosphate (SCOP) salts as amorphous reaction products were responsible for the development of this strength. When this CPC specimen was exposed in an autoclave, in-situ amorphous-crystal conversions, such as SCOP-hydroxyapatite (HOAp), and (Al2O3)((x)H2O)- gamma-AlOOH, occurred at nearly equal 100 deg C, while the rate of reaction of the residual CAC with the phosphate reactant was increasingly accelerated by hydrothermal catalysis. Based upon this information, lightweight CPC specimens by hydrothermally treating a low-density cement slurry (1.28 g/cm3) consisting of CAC powder, -(-NaPO3-)-n solution, and mullite-hollow microspheres were prepared. The characteristics of the autoclaved lightweight specimens were a compressive strength of >9.0 MPa, water permeability of approx. 5.0x10-3 millidarcy, and a low rate of alkali carbonation rate reflected the presence of a minimum amount of residual CAC, in conjunction with the presence of HOAp and gamma-AlOOH phases that are unsusceptible to wet carbonation.
Sodium phosphate-derived calcium phosphate cements
Calcium phosphate cements (CPC) were synthesized by the acid-base reaction between sodium phosphate, NaH2PO4 or -(-NaPO3-)-n, as the acid solution, and calcium aluminate cements (CAC) as the base reactant at 25 deg C. The extent of reactivity of -(-NaPO3-)-n with CAC was much higher than that of NaH2PO4, thereby resulting in a compressive strength of >20 MPa. Sodium calcium orthophosphate (SCOP) salts as amorphous reaction products were responsible for the development of this strength. When this CPC specimen was exposed in an autoclave, in-situ amorphous-crystal conversions, such as SCOP-hydroxyapatite (HOAp), and (Al2O3)((x)H2O)- gamma-AlOOH, occurred at nearly equal 100 deg C, while the rate of reaction of the residual CAC with the phosphate reactant was increasingly accelerated by hydrothermal catalysis. Based upon this information, lightweight CPC specimens by hydrothermally treating a low-density cement slurry (1.28 g/cm3) consisting of CAC powder, -(-NaPO3-)-n solution, and mullite-hollow microspheres were prepared. The characteristics of the autoclaved lightweight specimens were a compressive strength of >9.0 MPa, water permeability of approx. 5.0x10-3 millidarcy, and a low rate of alkali carbonation rate reflected the presence of a minimum amount of residual CAC, in conjunction with the presence of HOAp and gamma-AlOOH phases that are unsusceptible to wet carbonation.
Sodium phosphate-derived calcium phosphate cements
Aus Natriumphosphat synthetisierte Calciumphosphatzemente
Sugama, Toshifumi (author) / Carciello, N.R. (author)
Cement and Concrete Research ; 25 ; 91-101
1995
11 Seiten, 7 Bilder, 2 Tabellen, 8 Quellen
Article (Journal)
English
Infrarotprüfung , Bindemittel , Calciumphosphat , Aluminiumhydroxid , amorpher Zustand , Gasdurchlässigkeit , Druckfestigkeit , Natriumphosphatbinder , Infrarotspektroskopie , hydraulisches Bindemittel , Calciumaluminatbinder , Autoklavierung , Phosphatbinder , Hydroxylapatit , Böhmit , hydrothermale Reaktion
Sodium Phosphate-Derived Calcium Phosphate Cements
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