Surface Properties of HAp Particles Obtained by Hydrothermal Decomposition of Urea and Calcium-EDTA Chelates

Dj. Janaćković; I. Jankovic-Castvan; R. Petrović; Lj. Kostic-Gvozdenovic; S.K. Milonjić; Dragan P. Uskokovic

doi:10.4028/www.scientific.net/KEM.240-242.437

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Surface Properties of HAp Particles Obtained by Hydrothermal Decomposition of Urea and Calcium-EDTA Chelates

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Key Engineering Materials (Volumes 240-242)

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437-440

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https://doi.org/10.4028/www.scientific.net/KEM.240-242.437

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Online since:

May 2003

Authors:

Dj. Janaćković, I. Jankovic-Castvan, R. Petrović, Lj. Kostic-Gvozdenovic, S.K. Milonjić, Dragan P. Uskokovic

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Calcium-EDTA Chelates, Hydrothermal Decomposition, Hydroxyapatite (HAP), Surface Properties, Urea

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References

[1] R.P. Shellis, A.R. Lee and R.M. Wilson: J.Colloid Interface Sci. Vol. 218 (1999), p.351.

Google Scholar

[2] A.A. Baig, J.L. Fox, J.Hsu, Z.Wang, M.Otsuka, W.I. Higuchi and Racquel Z.LeGeros: J.Colloid Interface Sci. Vol. 179 (1996), p.608.

Google Scholar

[3] I.D. Smiciklas, S.K. Milonjic, P.Pfendt and S.Raicevic: Sep.Purif.Technol. Vol. 18 (2000), p.185.

Google Scholar

[4] L.C. Bell, A.M. Posner and J.P. Quirk: J.Colloid Interface Sci. Vol. 42 (1973), p.250.

Google Scholar

[5] J.Perrone, B.Fourest and E.Giffaut: J.Colloid Interface Sci. Vol. 249 (2002), p.441.

Google Scholar

[6] Y.Fujishiro, T.Sato and A.Okuwaki: J.Mater.Sci. Vol. 6 (1994), p.172.

Google Scholar

[7] Y.Fujishiro, A.Fujimoto, T.Sato and A.Okuwaki: J.Coloid Interface Sci. Vol. 173 (1995), p.119.

Google Scholar

[8] Y.Fujishiro, T. Sato and A. Okuwaki: Proc.PacRim 2, Cairns, Australia, 1996, p.18.

Google Scholar

[9] Dj.Janackovic, I.Petrovic-Prelevic, Lj.Kostic-Gvozdenovic, R.Petrovic, V.Jokanovic, D.Uskokovic: Key Engin.Mater. Vol. 192-195 (2000), p.203.

DOI: 10.4028/www.scientific.net/kem.192-195.203

Google Scholar

[10] S.K. Milonjic, A.L. Ruvarac, M.V. Susic, Thermochim. Acta, Vol. 11 (1975), p.261.

Google Scholar

[11] R.O. James, J.A. Davis and J.O. Leckie: J.Colloid Interface Sci. Vol. 65 (1978), p.331. 0 1 2 3 4 5 6 0 20 40 60 80 100 pH=9.61 pH=11.9 pH=8.05 pH=7.21 h (column hight), ml τ, hours

Google Scholar