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Bioinspired synthesis of calcium carbonate colloid particles

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Warianty tytułu
PL
Bioinspirowana synteza koloidalnych ziarn węglanu wapnia
Języki publikacji
EN
Abstrakty
EN
Biomimetic procedure for nucleation and growth of CaCO3 has been presented. The wet chemical syntheses of CaCO3 colloidal particles have been carried out. The characterization of precipitated particles of CaCO3 has been done using the particle size distribution analysis. The effect of physical and chemical parameters on the size of precipitated particles of CaCO3 has been investigated. This research may provide new insight into the precipitation of calcium carbonate.
PL
Zaprezentowano biomimetyczną procedurę zarodkowania wzrostu CaCO3 przeprowadzając chemiczna syntezę „na mokro” koloidalnych cząstek CaCO3. Dokonano charakterystyki wytrąconych cząstek przez wyznaczenie ich składu ziarnowy. Badano też fizyczne i chemiczne parametry wytrąconych ziarn CaCO3. Badania te mogą dostarczyć nowego spojrzenia na precypitację węglanu wapnia.
Rocznik
Tom
Strony
205--214
Opis fizyczny
Bibliogr. 24 poz.
Twórcy
autor
autor
autor
autor
Bibliografia
  • 1. ARAS J.L., FERNANDEZ S.M., 2003, Biomimetic process through the study of mineralized shells, Materials Characterization, 50, 189-195.
  • 2. CÖLFEN H., 2003, Precipitation of carbonates: recent progress in controlled production of complex shapes, Current Opinion Colloid Inter. Sci., 8, 23-31.
  • 3. DUJARDIN E., MANN S., 2002, Bio-inspired materials chemistry, Advanced Materials, 14 (11), 1-14.
  • 4. FALINI G., 2000, Crystallization of calcium carbonates in biologically inspired collagenous matrices, Inter. J. Inorganic materials, 2, 455-461.
  • 5. FALINI G., FERMANI S., RIPAMONTI A., 2002, Crystallization of calcium carbonate salts into betachitin scaffold, J. Inorganic Biochemistry, 91, 475-480.
  • 6. FENG L.Q., PU G., PEI Y., CUI Z.F., LI D.H., KIM N.T. 2000, Polymorph and morphology of calcium carbonate crystals induced by proteins extracted from mollusk shell, J.Crystal Growth, 216, 459-465.
  • 7. FISCHER K.E., ALEMAN J.B., TAO L.S, DANIELS H.R., LI M.E., BUNGER D.M., NAGARAJ G., SIGH P., ZETTL A., DESAI A.T., 2009, Biomimetic nanowire coatings for next generation adhesive drug delivery systems, Nano Letter, 9, (2), 716-720.
  • 8. FUJIWARA M., SHIOKAWA K., MORIGAKI K., ZHU Y., NAKAHARA Y., 2008, Calcium carbonate microcapsules encapsulating biomacromolecules, Chemical Engin. J., 137. 14-22.
  • 9. GROSSMANN O., LÖBMAN P., 2004, Biomimetic nucleation and growth of CaCO3 in hydrogels incorporating carboxylate groups, Biomaterials, 25,277-282.
  • 10. GUO F., LI Y., HU H-X., ZHAO Q-G., HE X-J., 2007, Size-controllable synthesis of calcium carbonate nanoparticles using aqueous foam films as templates, Material Letters, 61, 4937-4939.
  • 11. GUPTA R., 2004, Synthesis of precipitated calcium carbonate nanoparticles using modified emulsion membranes, Master thesis, Georgia Institute of Technology, USA.
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  • 13. JIAO Y., FENG Q., LI X., 2006, The co-effect of collagen and magnesium ions on calcium carbonate biomineralization, Materials Sci., Engin., C., 26, 648-652.
  • 14. KARAGIOZOV C., MOMCHILOVA D., 2005, Synthesis of nano-sized particles from metal carbonates by the method of reversed micells, Chemical Eng. Process., 44, 115-119.
  • 15. LI P., HE W., ZHOA H., WANG S., 2009, Biomimetic synthesis and characterization of the positive electrode material LiFePO4, J. Alloys Compounds, 471, 536-538.
  • 16. MANN S., 2001, Biomineralization principles and concepts in bioinorganic materials chemistry, Oxford University Press,
  • 17. MENAHEM T., MASTAI Y., 2008, Controlled crystallization of calcium carbonate susperstructures in macroemulsions, J. Crystal Growth, 310, 3552-2556.
  • 18. MISHRA S., SONAWANE H.S., SINGH P.R., 2005, Studies on characterization of nano CaCO3, prepared by the in situ deposition technique and it application in PP-nano CaCO3 composites, J. Polym. Sci., B., 43, 107-113.
  • 19. RODRIGUEZ-NAVARRO C., JIMENEZ-LOPEZ C., RODRIGEUEZ-NAVARRO a., GONZALEZMUNOZ T.M., RODRIGUEZ-GALLEGO M., 2007, Bacteria mediated mineralization of veterite, Geochem. Cosmochim. Acta, 71, 1197-1213.
  • 20. SHEN H.F., FENG L.Q., WANG M.C., 2002, The modulation of callogen on crystal morphology of calcium carbonate, J.Crystal Growth, 242, 239-244.
  • 21. UENO Y., FUTAGAWA h., TAKAGI Y., UENO A., MIZUSHIMA Y., 2005, Drug-incorporating calcium carbonate nanoparticles for a new delivery system, J.Controlled Release, 103, 93-98.
  • 22. VOINESCU E.A., TOURAUD D., LECKER A. PFITZNER A., KUNZ W., NINHAM W B., 2007, Mineralization of CaCO3 in the presence of egg white lysozyme, Langmuir, 23, 12269-12274.
  • 23. WANG C., ZHAO J., ZHAO X., BALA H., WANG Z., 2006, Synthesis of nanosized calcium carbonate (aragonite) via a polyacrylamid inducing process, Powder Technology, 163, 134-138.
  • 24. ZHAO h., HE W., WANG Y., YUE Y., GAO X., LI Z., YAN S., ZHOU W., ZHANG X., 2008, Biomineralizing synthesis of mesoporous hydroxyapatite-calcium pyrophosphate polycristal rusing ovalbumin as biosurfactant, Materials Chemistry Physics, 111, 265-270.
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-article-BAT6-0013-0020
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