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Online since: April 2015
Authors: Bin Li, Hai Kuan Liu, Si Qing Wang, Kun Liu, Chang Rui Zhang
Ohji, High performance porous silicon nitrides, Journal of the European Ceramic Society. 22 (2002) 2489–2494
C Tang, Boron nitride nanotubes, Materials Science and Engineering R. 70 (2010) 92–111 [11] J.
Kim, Formation of rod-like Si3N4 grains in porous SRBSN bodies using 6Y2O3-2MgO sintering additive, Ceramics International. 35 (2009) 2305–2310 [13] T.
Ohji, Microstructural design and mechanical properties of porous silicon nitride ceramics, Materials Science and Engineering A. 498 (2008) 5–11 [14] W.
Zhang, Effect of sintering temperature on microstructure and mechanical properties of highly porous silicon nitride ceramics produce by freeze casting, Materials Science and Engineering A. 527 (2010) 6501–6504
C Tang, Boron nitride nanotubes, Materials Science and Engineering R. 70 (2010) 92–111 [11] J.
Kim, Formation of rod-like Si3N4 grains in porous SRBSN bodies using 6Y2O3-2MgO sintering additive, Ceramics International. 35 (2009) 2305–2310 [13] T.
Ohji, Microstructural design and mechanical properties of porous silicon nitride ceramics, Materials Science and Engineering A. 498 (2008) 5–11 [14] W.
Zhang, Effect of sintering temperature on microstructure and mechanical properties of highly porous silicon nitride ceramics produce by freeze casting, Materials Science and Engineering A. 527 (2010) 6501–6504
Online since: June 2015
Authors: Eduardo de Sousa Lima, A.P.O. Santos, R.F. Cabral, L.M. Itaboray, C. Santos
Matson: Journal of Ceramic Processing Research Vol. 5 (2004), p. 380
Gao: Ceramics International Vol. 27 (2001), p. 721
Marshall: Journal of American Ceramic Society Vol. 64 (1981), p. 533
Uchida: Journal of the European Ceramic Society Vol. 22 (2002), p. 2621
Salazar: Journal of American Ceramic Society Vol. 88 (2005), p. 1488.
Gao: Ceramics International Vol. 27 (2001), p. 721
Marshall: Journal of American Ceramic Society Vol. 64 (1981), p. 533
Uchida: Journal of the European Ceramic Society Vol. 22 (2002), p. 2621
Salazar: Journal of American Ceramic Society Vol. 88 (2005), p. 1488.
Online since: April 2005
Authors: Sabine Begand, Wilfried Glien, Thomas Oberbach
We found that the hydrothermal treatment
of the ATZ ceramic did not significantly influence these parameters, unlike those of a single-phase
ZrO2 ceramic.
The mechanical parameters obtained with ZTA ceramics are between those of the two single-phase Al2O3 and ZrO2 materials, whereas the strengths achieved with ATZ ceramics are markedly above those of any ZrO2 ceramics.
ATZ ceramic offers increased strength and fracture toughness connected with improvement of reliability and safety of the composite ceramic.
DKG 79 (2002) No.5 : E27-E31 [4] ISO 6474: Implants for surgery-Ceramic materials based on high purity alumina; International Organization for Standartization; 1994 [5] Chevalier: Low Temperature Ageing of Y-TZP Ceramics; Journal of American Ceramic Society 82; 1999; S.2150-2154 [6] Herrmann, Schilm, Michael, Adler: Corrosion Behaviour of Different Technical Ceramics in Acids, Basic Solutions and under Hydrothermal Conditions; cfi/Ber.
DKG 80; 2003; No.4; S.E 27-34 [7] Lawson, Gill, Dransfield: Hydrothermal and Corrosive Degradation of Y-TZP; Key Engineering Materials Vol. 113; 1996; S. 207-214 [8] M.Hirano, H.Inada: Hydrothermal stability of yttria- and ceria.doped tetragonal zirconia-alumina composites; Journal of Material Science 26; 1991; S. 5047-5052 [9] J.J.Swab:Low temperature degradation of Y-TZP materials; Journal of Material Science 26; 1991; S.6706 [10] ISO standard 7206/2: Implants for surgery - Partial and total hip joint prostheses Part 2: Articulating surfaces made of metallic, ceramic and plastics materials; International Organization for Standardization; 1996
The mechanical parameters obtained with ZTA ceramics are between those of the two single-phase Al2O3 and ZrO2 materials, whereas the strengths achieved with ATZ ceramics are markedly above those of any ZrO2 ceramics.
ATZ ceramic offers increased strength and fracture toughness connected with improvement of reliability and safety of the composite ceramic.
DKG 79 (2002) No.5 : E27-E31 [4] ISO 6474: Implants for surgery-Ceramic materials based on high purity alumina; International Organization for Standartization; 1994 [5] Chevalier: Low Temperature Ageing of Y-TZP Ceramics; Journal of American Ceramic Society 82; 1999; S.2150-2154 [6] Herrmann, Schilm, Michael, Adler: Corrosion Behaviour of Different Technical Ceramics in Acids, Basic Solutions and under Hydrothermal Conditions; cfi/Ber.
DKG 80; 2003; No.4; S.E 27-34 [7] Lawson, Gill, Dransfield: Hydrothermal and Corrosive Degradation of Y-TZP; Key Engineering Materials Vol. 113; 1996; S. 207-214 [8] M.Hirano, H.Inada: Hydrothermal stability of yttria- and ceria.doped tetragonal zirconia-alumina composites; Journal of Material Science 26; 1991; S. 5047-5052 [9] J.J.Swab:Low temperature degradation of Y-TZP materials; Journal of Material Science 26; 1991; S.6706 [10] ISO standard 7206/2: Implants for surgery - Partial and total hip joint prostheses Part 2: Articulating surfaces made of metallic, ceramic and plastics materials; International Organization for Standardization; 1996
Online since: August 2018
Authors: Jun Shou Li, Xiang Jun Tang, Li Qing, Fang Zhao
W., EI-Raghy T., Synthesis and characterization of remarable ceramic: Ti3SiC2, Journal of the American Ceramic Society. 79(1997) 1953-1956
[4] Chen K.X., Guo J.M., Ge Z.B., A Novel Route for Preparing Ti3SiC2 Ceramics, Rare Metal Materials and Engineering. 31(2002) 20-23
[6] Shi S.L., Li J.S., Study of Machinable Properties of Ti3SiC2/3Y-TZP Ceramics Composites, Rare Metal Materials and Engineering. 36(2007) 215-217
[10] Zhang W.X., Xia T., Luo W., Liang B.Y., Fabricating Ti3SiC2-diamond Composites by Spark Plasma Sintering Induced Self-propagation Reaction, Diamond & Abrasives Engineering. 37(2017) 43-46
[13] Schaffer J., AsgokSaxena, The Science and Design of Engineering Materials, America: Mc GrawHill. (1999).
[4] Chen K.X., Guo J.M., Ge Z.B., A Novel Route for Preparing Ti3SiC2 Ceramics, Rare Metal Materials and Engineering. 31(2002) 20-23
[6] Shi S.L., Li J.S., Study of Machinable Properties of Ti3SiC2/3Y-TZP Ceramics Composites, Rare Metal Materials and Engineering. 36(2007) 215-217
[10] Zhang W.X., Xia T., Luo W., Liang B.Y., Fabricating Ti3SiC2-diamond Composites by Spark Plasma Sintering Induced Self-propagation Reaction, Diamond & Abrasives Engineering. 37(2017) 43-46
[13] Schaffer J., AsgokSaxena, The Science and Design of Engineering Materials, America: Mc GrawHill. (1999).
Online since: August 2022
Authors: Israa K. Sabree, Ola Saleh Mahdi, Fatima Shaker, Mariam Ibrahim
Pena.; Bone-Like Apatite-Forming Ability of Ca3(PO4)2-CaMg(SiO3)2 Ceramics in Simulated Body Fluid; Key Engineering Materials, (2009), Vols. 396-398, pp 103-106
Edrees, effects of MgO wt.% on the structure, mechanical, and biological properties of bioactive glass-ceramics in the SiO2,Na2O,CaO,P2O5,MgO system, International Journal of Mechanical Engineering and Technology (IJMET) Volume 10, Issue 01, January (2019), 97–106
Sadami, Study of diopside ceramics for biomaterials, Journal of Materials Science: Materials in Medicine, (1999), volume 10, 475–479
Chang, Degradation, Bioactivity, and Cytocompatibility of Diopside, Akermanite, and Bredigite Ceramics, Biomaterials and Tissue Engineering Research Center, (2006)
Journal of the Australian Ceramic Society, (2018)
Edrees, effects of MgO wt.% on the structure, mechanical, and biological properties of bioactive glass-ceramics in the SiO2,Na2O,CaO,P2O5,MgO system, International Journal of Mechanical Engineering and Technology (IJMET) Volume 10, Issue 01, January (2019), 97–106
Sadami, Study of diopside ceramics for biomaterials, Journal of Materials Science: Materials in Medicine, (1999), volume 10, 475–479
Chang, Degradation, Bioactivity, and Cytocompatibility of Diopside, Akermanite, and Bredigite Ceramics, Biomaterials and Tissue Engineering Research Center, (2006)
Journal of the Australian Ceramic Society, (2018)
Online since: September 2022
Authors: Rozana Aina Maulat Osman, Mohd Sobri Idris, Nur Izzati Muhammad Nadzri, Domingo Arturo Ruiz León, Ku Noor Dhaniah Ku Muhsen
Structural, Microstructural and Dielectric Properties
of BaTi0.905Sn0.095O3 Ceramic
Ku Noor Dhaniah KU MUHSEN1,2,a, Rozana Aina Maulat OSMAN1,2,b,*,
Mohd Sobri IDRIS2,3,c, Nur Izzati MUHAMMAD NADZRI2,3,d
and RUIZ León Domingo Arturo4,e
1Faculty of Electronic Engineering Technology, Universiti Malaysia Perlis, 02600 Arau, Perlis, Malaysia
2Materials Engineering Programme, Faculty of Chemical Engineering Technology, Universiti Malaysia Perlis, 02600 Arau, Perlis, Malaysia
3Center of Excellence Frontier Materials Research, Universiti Malaysia Perlis, 01000 Kangar, Perlis, Malaysia
4Chemistry Materials Department, Universidad de Santiago de Chile, Av.
Journal of Alloys and Compounds, 712, 1-6
Journal of Applied Crystallography, 49(5), 1726-1733
Journal of the European Ceramic Society, 27(2-3), 505-509
Ceramics International, 47(9), 13107-13117
Journal of Alloys and Compounds, 712, 1-6
Journal of Applied Crystallography, 49(5), 1726-1733
Journal of the European Ceramic Society, 27(2-3), 505-509
Ceramics International, 47(9), 13107-13117
Online since: March 2010
Authors: Yun Feng Liu, Fu Dong Zhu, Xing Tao Dong
Fisher, In: Engineering of functional skeletal tissues (Springer,
London, 2007)
Lin: Materials Science and Engineering C, Vol. 28 (2008), p. 51-56 [11] L.
Dedoussis: International Journal of Advanced Manufactruring Technology, Vol. 40 (2009), p. 116-127 [14] Q.B.
Schmitt: International Journal of Advanced Manufacturing Technology, Vol. 29 (2006), p. 317-335 [15] I.
Chua: Tissue Engineering, Vol. 8 (2002), p. 1-11 [19] K.F.
Lin: Materials Science and Engineering C, Vol. 28 (2008), p. 51-56 [11] L.
Dedoussis: International Journal of Advanced Manufactruring Technology, Vol. 40 (2009), p. 116-127 [14] Q.B.
Schmitt: International Journal of Advanced Manufacturing Technology, Vol. 29 (2006), p. 317-335 [15] I.
Chua: Tissue Engineering, Vol. 8 (2002), p. 1-11 [19] K.F.
Online since: October 2010
Authors: Wei Hong Zhang, Ji Hong Zhu, Xiao Jun Gu
Introduction
Topology optimization and its engineering application are among the most popular research topics in
the field of structural optimization and computational mechanics [1].
Tromans: Developments in Rapid Casting (Professional Engineering Publishing, London 2003) [4] R.
Dickens: Rapid Prototyping Journal Vol. 7 (2001), p. 66-72 [5] C.
Braibant: International Journal of Numerical Methods in Engineering Vol. 23 (1986), p. 409-428 [6] K.
Svanberg: International Journal for Numerical Methods in Engineering Vol. 24 (1987), p. 359-373
Tromans: Developments in Rapid Casting (Professional Engineering Publishing, London 2003) [4] R.
Dickens: Rapid Prototyping Journal Vol. 7 (2001), p. 66-72 [5] C.
Braibant: International Journal of Numerical Methods in Engineering Vol. 23 (1986), p. 409-428 [6] K.
Svanberg: International Journal for Numerical Methods in Engineering Vol. 24 (1987), p. 359-373
Online since: July 2017
Authors: Fernand Marqui, Karlo Barbakadze, Ekaterine Sanaia, Guram Bokuchava, Tinatin Kuchukhidze, Natia Jalagonia
Obtaining of Graphene Structure Containing Ceramic Composites in High Temperature Vacuum Furnace
Natia Jalagonia1,a, Fernand Marquis2,b, Karlo Barbakadze1,c,
Ekaterine Sanaia1,d, Guram Bokuchava1,e, Tinatin Kuchukhidze1,f
1Ilia Vekua Sukhumi Institute of Physics and Technologies, 7 Mindeli Str., 0186, Tbilisi, Georgia
2Department of Mechanical Engineering, San Diego State University San Diego, CA 92182, USA
E-mail: anati.jalagonia@gmail.com, bfmarquis@mail.sdsu.edu, cbarbaqa@gmail.com, desanaia@gmail.com, esipt@sipt.org, ftinikokuchukhidze@gmail.com
Keywords: Graphene oxide, Alumina, Powdery composite, Organic binder, High temperature vacuum furnace.
Some characteristics of ceramic materials have been improved.
Journal of Colloid and Interface Science 351 (2010) 122-127
Proceedings of International Conference on Advanced Materials and Technologies, (2015), 19-23
International Science Index (2015), 17, 1303-1307.
Some characteristics of ceramic materials have been improved.
Journal of Colloid and Interface Science 351 (2010) 122-127
Proceedings of International Conference on Advanced Materials and Technologies, (2015), 19-23
International Science Index (2015), 17, 1303-1307.
Online since: February 2013
Authors: Han Xing Liu, Hua Hao, Ming He Cao, Gui Fang Zhang
Materials Science and Engineering: B, Vol. 99 (2003), p. 226–229
Ceramics International, Vol. 34 (2008), p. 873–876
Journal of Materials Science: Materials in Electronics, Vol. 18 (2007), p. 381-384
Journal of the European Ceramic Society, Vol.29 (2009), p. 1501–1506
Journal of the European Ceramic Society, Vol. 24 (2004), p. 3303–3306.
Ceramics International, Vol. 34 (2008), p. 873–876
Journal of Materials Science: Materials in Electronics, Vol. 18 (2007), p. 381-384
Journal of the European Ceramic Society, Vol.29 (2009), p. 1501–1506
Journal of the European Ceramic Society, Vol. 24 (2004), p. 3303–3306.