Sintering and properties of dense manganese-doped calcium phosphate bioceramics prepared using sol-gel derived nanopowders
Dense manganese-doped biphasic calcium phosphate (Mn-BCP) ceramics were fabricated via uniaxial pressing using the sol-gel derived powders. The compacted discs were sintered in ambient atmosphere with temperatures ranging from 800C to 1400C. Manganese (Mn) level was varied in the range of 0.6, 1.9,...
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my.uniten.dspace-305012023-12-29T15:48:33Z Sintering and properties of dense manganese-doped calcium phosphate bioceramics prepared using sol-gel derived nanopowders Sopyan I. Nawawi N.A. Shah Q.H. Ramesh S. Tan C.Y. Hamdi M. 23482484000 35488532000 6602268356 41061958200 16029485400 17433807000 Biomaterials Ceramics Characterization Dopant Manganese Mechanical Nanomaterials Atmospheric temperature Bioceramics Biological materials Calcium phosphate Doping (additives) Fracture toughness Gels Grain growth Manganese Mechanical properties Nanostructured materials Phase stability Phosphates Powders Sol-gel process Sol-gels Sols Ambient atmosphere Biphasic calcium phosphates Ceramics Dopant Maximum hardness Mechanical Mn-doped Mn-doping Nano powders Physical and mechanical properties Relative density Sintering properties Sintering temperatures Sol-gel derived powders Tcp Phases Temperature range Uni-axial pressing Sintering Dense manganese-doped biphasic calcium phosphate (Mn-BCP) ceramics were fabricated via uniaxial pressing using the sol-gel derived powders. The compacted discs were sintered in ambient atmosphere with temperatures ranging from 800C to 1400C. Manganese (Mn) level was varied in the range of 0.6, 1.9, 4.3, and 11.9mol%, and its effect on physical and mechanical properties of the dense samples were investigated. All dense samples have been proved to show HA and -TCP phases only. Mn doping has shifted the onset of the sintering temperature of the BCP, leading to the improved densification of BCP ceramics. The relative density also increased with sintering temperature. Considerable grain growth has been observed for Mn-doped BCP samples when compared to the undoped BCP. Furthermore, 11.9mol% Mn-doped BCP dense samples showed the maximum hardness of 6.66GPa compared to 2.89GPa for the undoped BCP. The incorporation of Mn was also found to be beneficial in enhancing the fracture toughness of BCP throughout the temperature range employed. This study has shown that Mn doping was effective in improving the sintering properties of BCP without affecting the phase stability. Copyright � Taylor & Francis Group, LLC. Final 2023-12-29T07:48:33Z 2023-12-29T07:48:33Z 2011 Article 10.1080/10426914.2011.557285 2-s2.0-79960693188 https://www.scopus.com/inward/record.uri?eid=2-s2.0-79960693188&doi=10.1080%2f10426914.2011.557285&partnerID=40&md5=59eae4534a4215b9ef2e6cded7bcd4f6 https://irepository.uniten.edu.my/handle/123456789/30501 26 7 908 914 Scopus |
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Biomaterials Ceramics Characterization Dopant Manganese Mechanical Nanomaterials Atmospheric temperature Bioceramics Biological materials Calcium phosphate Doping (additives) Fracture toughness Gels Grain growth Manganese Mechanical properties Nanostructured materials Phase stability Phosphates Powders Sol-gel process Sol-gels Sols Ambient atmosphere Biphasic calcium phosphates Ceramics Dopant Maximum hardness Mechanical Mn-doped Mn-doping Nano powders Physical and mechanical properties Relative density Sintering properties Sintering temperatures Sol-gel derived powders Tcp Phases Temperature range Uni-axial pressing Sintering |
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Biomaterials Ceramics Characterization Dopant Manganese Mechanical Nanomaterials Atmospheric temperature Bioceramics Biological materials Calcium phosphate Doping (additives) Fracture toughness Gels Grain growth Manganese Mechanical properties Nanostructured materials Phase stability Phosphates Powders Sol-gel process Sol-gels Sols Ambient atmosphere Biphasic calcium phosphates Ceramics Dopant Maximum hardness Mechanical Mn-doped Mn-doping Nano powders Physical and mechanical properties Relative density Sintering properties Sintering temperatures Sol-gel derived powders Tcp Phases Temperature range Uni-axial pressing Sintering Sopyan I. Nawawi N.A. Shah Q.H. Ramesh S. Tan C.Y. Hamdi M. Sintering and properties of dense manganese-doped calcium phosphate bioceramics prepared using sol-gel derived nanopowders |
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Dense manganese-doped biphasic calcium phosphate (Mn-BCP) ceramics were fabricated via uniaxial pressing using the sol-gel derived powders. The compacted discs were sintered in ambient atmosphere with temperatures ranging from 800C to 1400C. Manganese (Mn) level was varied in the range of 0.6, 1.9, 4.3, and 11.9mol%, and its effect on physical and mechanical properties of the dense samples were investigated. All dense samples have been proved to show HA and -TCP phases only. Mn doping has shifted the onset of the sintering temperature of the BCP, leading to the improved densification of BCP ceramics. The relative density also increased with sintering temperature. Considerable grain growth has been observed for Mn-doped BCP samples when compared to the undoped BCP. Furthermore, 11.9mol% Mn-doped BCP dense samples showed the maximum hardness of 6.66GPa compared to 2.89GPa for the undoped BCP. The incorporation of Mn was also found to be beneficial in enhancing the fracture toughness of BCP throughout the temperature range employed. This study has shown that Mn doping was effective in improving the sintering properties of BCP without affecting the phase stability. Copyright � Taylor & Francis Group, LLC. |
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23482484000 |
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23482484000 Sopyan I. Nawawi N.A. Shah Q.H. Ramesh S. Tan C.Y. Hamdi M. |
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Sopyan I. Nawawi N.A. Shah Q.H. Ramesh S. Tan C.Y. Hamdi M. |
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Sopyan I. |
title |
Sintering and properties of dense manganese-doped calcium phosphate bioceramics prepared using sol-gel derived nanopowders |
title_short |
Sintering and properties of dense manganese-doped calcium phosphate bioceramics prepared using sol-gel derived nanopowders |
title_full |
Sintering and properties of dense manganese-doped calcium phosphate bioceramics prepared using sol-gel derived nanopowders |
title_fullStr |
Sintering and properties of dense manganese-doped calcium phosphate bioceramics prepared using sol-gel derived nanopowders |
title_full_unstemmed |
Sintering and properties of dense manganese-doped calcium phosphate bioceramics prepared using sol-gel derived nanopowders |
title_sort |
sintering and properties of dense manganese-doped calcium phosphate bioceramics prepared using sol-gel derived nanopowders |
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2023 |
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1806425644190400512 |