Multifunctional advanced ceramics from preceramic polymers and nano-sized active fillers

Journal of the European Ceramic Society

Volumn 33, Issue 3, 2013, Pages 453-469

  Colombo, P ^a,b   Bernardo, E ^a   Parcianello, G ^a  

^a UNIVERSITY OF PADOVA   (Italy)

^b PENNSYLVANIA STATE UNIVERSITY   (United States)

Author keywords

Microstructure final; Nanocomposites; Polymer derived ceramics; Precursors organic; Shaping

Indexed keywords

3-D PRINTING; ACTIVE FILLERS; ADVANCED CERAMICS; BIOACTIVE CERAMIC; BULK COMPONENTS; CERAMIC COMPONENT; COMPOSITIONAL RANGE; ENVIRONMENTAL BARRIER COATINGS; HEATING TIME; LOW TEMPERATURES; MICROSTRUCTURE-FINAL; OXIDE SYSTEMS; OXYNITRIDES; PLASTIC FORMING; POLYMER-DERIVED-CERAMICS; POTENTIAL APPLICATIONS; PRECERAMIC POLYMER; PRECURSORS-ORGANIC; SHAPING; SIALONS;

CERAMIC MATERIALS; EXTRUSION; INORGANIC COATINGS; NANOCOMPOSITES; NITRIDES; POLYMERS; PRESSING (FORMING); REACTION KINETICS; SILICATE MINERALS; YTTRIUM; YTTRIUM OXIDE;

STRUCTURAL CERAMICS;

EID: 84870293915     PISSN: 09552219     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.jeurceramsoc.2012.10.006     Document Type: Article

References (100)

1. Colombo P., Mera G., Riedel R., Sorarù G.D. Polymer-derived-ceramics: 40 years of research and innovation in advanced ceramics. J Am Ceram Soc 2010, 93:1805-1837.
2. Colombo P., Sorarù G.D., Riedel R., Kleebe H.-J. Polymer derived ceramics. From nano-structure to applications 2009, DESTech Publications, Lancaster, PA.
3. Greil P. Active-filler-controlled pyrolysis of preceramic polymers. J Am Ceram Soc 1995, 78:835-848.
4. Greil P. Near net shape manufacturing of polymer derived ceramics. J Eur Ceram Soc 1998, 18:1095-1114.
5. Greil P. Polymer derived engineering ceramics. Adv Eng Mater 2000, 2:339-348.
6. Greil P., Seibold M. Modelling of dimensional changes during polymer-ceramic conversion for bulk component fabrication. J Mater Sci 1992, 27:1053-1060.
7. Greil P. Polymer-filled derived ceramics with hierarchical microstructures. Key Eng Mater 1999, 159-160:339-346.
8. Enry T., Seibold M., Jarchow O., Greil P. Microstructure development of oxycarbide composites during active-filler-controlled polymer pyrolysis. J Am Ceram Soc 1993, 76:207-213.
9. Seibold M., Greil P. Thermodynamics and microstructure development of ceramic composite formation by active-filler-controlled polymer pyrolysis (AFCOP). J Eur Ceram Soc 1993, 11:105-113.
10. Greil P. Advancements in polymer-filler derived ceramics. J Korean Ceram Soc 2012, 49:279-286.
11. Schwarz K.B., Rowcliffe D.J. Modeling density contributions in preceramic polymer/ceramic powder systems. J Am Ceram Soc 1986, 69:C106-C108.
12. Seyferth D., Bryson N., Workman D.P., Sobon C.A. Preceramic polymers as reagents in the preparation of ceramics. J Am Ceram Soc 1991, 74:2687-2689.
13. Yajima S. Special heat-resisting materials from organometallic polymers. Am Ceram Soc Bull 1983, 62:893-915.
14. Bougoin M., Thevenot F. Pressureless sintering of boron carbide with addition of polycarbosilane. J Mater Sci 1987, 22:109-114.
15. 4/polysilazane bodies during heating. Adv Ceram Mater 1988, 3:320-323.
16. Schwab S.T., Blanchard C.R., Graef R.C. The influence of preceramic binders on the microstructural development of silicon nitride. J Mater Sci 1994, 29:6320-6328.
17. 3-SiC composites prepared by warm pressing and sintering of an organosilicon polymer-coated alumina powder. J Eur Ceram Soc 2007, 27:2385-2392.
18. 4 composites employing polymer-derived SiAlOC as sintering aid. J Eur Ceram Soc 2010, 30:759-767.
19. Kang K-T., Kim D-J., Greil P. Development of novel ceramic composites by active filler controlled polymer pyrolysis with tungsten. J Korean Ceram Soc 1998, 35:939-944.
20. Dernovsek O., Bressiani J.C., Bressiani A.H.A., Greil P. Reaction bonded niobium carbide ceramics from polymer-filler mixtures. J Mater Sci 2000, 35:2201-2207.
21. 2C ceramics. Mater Sci Eng A 1999, 260:101-107.
22. Steinau M., Travitzky N., Gegner J., Hofmann J., Greil P. Polymer-derived ceramics for advanced bearing applications. Adv Ceram Mater 2008, 10:1141-1146.
23. Biasetto L., Francis A., Palade P., Principi G., Colombo P. Polymer-derived microcellular SiOC foams with magnetic functionality. J Mater Sci 2008, 43:4119-4126.
24. 2-derived composite ceramics. J Am Ceram Soc 2001, 84:2256-2259.
25. Walter S., Suttor D., Erny T., Hahn B., Greil P. Injection moulding of polysiloxane/filler mixtures for oxycarbide ceramic composites. J Eur Ceram Soc 1996, 16:387-393.
26. Colombo P., Gambaryan-Roisman T., Scheffler M., Buhler P., Greil P. Conductive ceramic foams from preceramic polymers. J Am Ceram Soc 2001, 84:2265-2268.
27. Suttor D., Kleebe H-J., Ziegler G. Formation of mullite from filled siloxanes. J Am Ceram Soc 1997, 80:2541-2548.
28. Anggono J., Derby B. Intermediate phases in mullite synthesis via aluminum- and alumina-filled polymethylsiloxane. J Am Ceram Soc 2005, 88:2085-2091.
29. Bernardo E., Colombo P., Pippel E., Woltersdorf J. Novel mullite synthesis based on alumina nanoparticles and a preceramic polymer. J Am Ceram Soc 2006, 89:1577-1583.
30. Bernardo E., Colombo P. Advanced oxide ceramics from a preceramic polymer and fillers. Soft Mater 2006, 4:175-185.
31. Bernardo E., Colombo P., Hampshire S. SiAlON-based ceramics from filled preceramic polymers. J Am Ceram Soc 2006, 89:3839-3842.
32. Griggio F., Bernardo E., Colombo P., Messing G.L. Kinetic studies of mullite synthesis from alumina nanoparticles and a preceramic polymer. J Am Ceram Soc 2008, 91:2529-2533.
33. Bernardo E., Tomasella E., Colombo P. Development of multiphase bioceramics from a filler-containing preceramic polymer. Ceram Int 2009, 35:1415-1421.
34. Bernardo E., Colombo P., Hampshire S. Advanced ceramics from preceramic polymers and nano-fillers. J Eur Ceram Soc 2009, 29:843-849.
35. Parcianello G., Bernardo E., Colombo P. Mullite/zirconia nano-composites from a preceramic polymer and nano-sized fillers. J Am Ceram Soc 2011, 94:1357-1362.
36. Bernardo E., Colombo P., Cacciotti I., Bianco A., Bedini R., Pecci R., et al. Porous wollastonite-hydroxyapatite bioceramics from a preceramic polymer and micro- or nano-sized fillers. J Eur Ceram Soc 2012, 32:399-408.
37. Bernardo E., Parcianello G., Colombo P., Jones B.H., Kruise J., Barnes A.T., et al. SiAlON ceramics from preceramic polymers and nano-sized fillers: application in ceramic joining. J Eur Ceram Soc 2012, 32:1329-1335.
38. Tkalcec E., Ivankovic H., Nass R., Schmidt H. Crystallization kinetics of mullite formation in diphasic gels containing different alumina components. J Eur Ceram Soc 2003, 23:1465-1475.
39. Ionescu E., Papendorf B., Kleebe H-J., Poli F., Müller K., Riedel R. Polymer-derived silicon oxycarbide/hafnia ceramic nanocomposites. Part I. Phase and microstructure evolution during the ceramization process. J Am Ceram Soc 2010, 93:1174-1182.
40. Papendorf B., Nonnenmacher K., Ionescu E., Kleebe H-J., Riedel R. Strong influence of polymer architecture on the microstructural evolution of hafnium-alkoxide-modified silazanes upon ceramization. Small 2011, 7:970-978.
41. Toma L., Fasel C., Lauterbach S., Kleebe H-J., Riedel R. Influence of nano-aluminum filler on the microstructure of SiOC ceramics. J Eur Ceram Soc 2011, 31:1779-1789.
42. Katsuda Y., Gerstel P., Narayanan J., Bill J., Aldinger F. Reinforcement of precursor-derived Si-C-N ceramics with carbon nanotubes. J Eur Ceram Soc 2006, 26:3399-3405.
43. Kokott S., Heymann L., Motz G. Processability of multi-walled carbon nanotubes-ABSE polycarbosilazane composites. J Eur Ceram Soc 2008, 28:1015-1021.
44. Li Y., Fernandez-Recio L., Gerstel G., Srot V., van Aken P.A., Kaiser G., et al. Chemical modification of single-walled carbon nanotubes for the reinforcement of precursor-derived ceramics. Chem Mater 2008, 20:5593-5599.
45. Shibuya M., Sakurai M., Takahashi T. Preparation and characteristics of a vapor-grown carbon fiber/ceramic composite using a methyl silicone precursor. Compos Sci Technol 2007, 67:3338-3344.
46. Ji F., Li Y-L., Feng J-M., Su D., Wen Y-Y., Feng Y., et al. Electrochemical performance of graphene nanosheets and ceramic composites as anodes for lithium batteries. J Mater Chem 2009, 19:9063-9067.
47. http://www.ing.unitn.it/~maud/.
48. Michalet T., Parlier M., Beclin F., Duclos R., Crampon J. Elaboration of low shrinkage mullite by active filler controlled pyrolysis of siloxanes. J Eur Ceram Soc 2002, 22:143-152.
49. Schneider H., Voll D., Saruhan B., Sanz J., Schrader G., Rüscher C., et al. Synthesis and structural characterization of non-crystalline mullite precursors. J Non-Cryst Solids 2004, 178:262-271.
50. Parcianello G., Bernardo E., Colombo P. Low temperature synthesis of zircon from silicone resins and oxide nano-sized particles. J Eur Ceram Soc 2012, 32:2819-2824.
51. Hong S.H., Messing G.L. Anisotropic grain growth in diphasic-gel-derived titania-doped mullite. J Am Ceram Soc 1998, 77:1269-1277.
52. Sacks M.D., Bozkurt N., Scheiffele G.W. Fabrication of mullite and mullite-matrix composites by transient viscous sintering of composite powders. J Am Ceram Soc 1991, 74:2428-2437.
53. 3 ceramics. Ceram Int 2006, 32:457-460.
54. Cortés E.C., Fuente J.A.M., Moreno J.M., Pérez C.P., Cordoncillo E.C., Castelló J.B.C. Solid-solution formation in the synthesis of Fe-zircon. J Am Ceram Soc 2004, 87:612-616.
55. Riedel R., Toma L., Fasel C., Miehe G. Polymer-derived mullite-SiC-based nanocomposites. J Eur Ceram Soc 2009, 29:3079-3090.
56. Bernardo E, Dias PM, Colombo P. Unpublished work.
57. 2 system. J Eur Ceram Soc 2005, 25:313-333.
58. Lee W.E., Heuer A.H. On the polymorphism of enstatite. J Am Ceram Soc 1987, 70:349-370.
59. 4 forsterite ceramics. Mater Lett 2008, 62:520-522.
60. Parcianello G, Bernardo E, Colombo P. Unpublished work.
61. Hamidouche M., Bouaouadja N., Osmani H., Torrecillias R., Fantozzi G. Thermomechanical behaviour of mullite-zirconia composite. J Eur Ceram Soc 1996, 16:441-445.
62. Parcianello G, Bernardo E, Colombo P. Optimization of phase purity of β'-Sialon ceramics produced from silazanes and nano-sized alumina. J Am Ceram Soc, doi:10.1111/j.%201551-2916.2012.05179.x.
63. Liu X-J., Sun X.W., Zhang J.J., Pu X.P., Ge Q.M., Huang L.P. Fabrication of β-SiAlON powder from kaolin. Mater Res Bull 2003, 38:1939-1948.
64. Zheng J., Forslund B. Carbothermal preparation of β-SiAlON powder at elevated nitrogen pressures. J Eur Ceram Soc 1999, 19:175-185.
65. Jacobson N.S., Lee K.N., Fox D.S. Reactions of silicon carbide and silicon (IV) oxide at elevated temperatures. J Am Ceram Soc 1992, 76:1603-1611.
66. Ewing H., Vital A., Vogt U., Hendry A. The nucleation and growth mechanism of Si-N-O fibres. Mater Sci Forum 2000, 325-326:37-42.
67. 2+ green phosphors synthesized by gas pressured sintering. J Ceram Soc Jpn 2008, 116:389-394.
68. Bernardo E., Parcianello G., Colombo P. Novel synthesis and applications of yttrium silicates from a silicone resin containing oxide nano-particle fillers. Ceram Int 2012, 38:5469-5474.
69. 3+ emission in Y-Si-O-N materials. J Alloys Compd 1998, 268:272-277.
70. Seryotkin Y.V., Sokol E.V., Kokh S.N. Natural pseudowollastonite: crystal structure, associated minerals, and geological context. Lithos 2012, 134-135:75-90.
71. 2 system. Phys Chem Miner 2000, 27:565-574.
72. da Rocha R.M., Greil P., Bressiani J.C., Bressiani A.H.A. Complex-shaped ceramic composites obtained by machining compact polymer-filler mixtures. Mater Res 2005, 8:191-196.
73. Vlasveld D.P.N., de Jong M., Bersee H.E.N., Gotsis A.D., Picken S.J. The relation between rheological and mechanical properties of PA6 nano- and micro-composites. Polymer 2005, 46:10279-10289.
74. Wang H., Zeng C., Elkovitch M., Lee L.J., Koelling K.W. Processing and properties of polymeric nano-composites. Polym Eng Sci 2001, 41:2036-2046.
75. Huang Y.Y., Terentjev E.M. Dispersion and rheology of carbon nanotubes in polymers. Int J Mater Form 2008, 1:63-74.
76. Hanemann T., Boehm J., Henzi P., Honnef K., Litfin K., Ritzhaupt-Kleissl E., et al. From micro to nano: properties and potential applications of micro- and nano-filled polymer ceramic composites in microsystem technology. IEE Proc-Nanobiotechnol 2004, 151:167-172.
77. Chen X., Wu L., Zhou S., You B. In situ polymerization and characterization of polyester-based polyurethane/nano-silica composites. Polym Int 2003, 52:993-998.
78. Zhang T., Evans J.R.G., Woodthorpe J. Injection moulding of silicon carbide using an organic vehicle based on a preceramic polymer. J Eur Ceram Soc 1995, 15:729-734.
79. Mott M., Evans J.R.G. Solid freeforming of silicon carbide by inkjet printing using a polymeric precursor. J Am Ceram Soc 2001, 84:307-313.
80. Nalawade S.P., Picchioni F., Janssen L.P.B.M. Supercritical carbon dioxide as a green solvent for processing polymer melts: processing aspects and applications. Prog Polym Sci 2006, 31:19-43.
81. Njuguna J., Pielichowski K., Desai S. Nanofiller-reinforced polymer nanocomposites. Polym Adv Technol 2008, 19:947-959.
82. Sui G., Zhong W.H., Yang X.P., Yu Y.H. Curing kinetics and mechanical behavior of natural rubber reinforced with pretreated carbon nanotubes. Mater Sci Eng A 2008, 485:524-531.
83. Ashby M.F. Materials selection in mechanical design 2005, Butterworth-Heinemann, Oxford, UK.
84. Ohsato H., Tsunooka T., Sugiyama T., Kakimoto K., Ogawa H. Forsterite ceramics for millimeterwave dielectrics. J Electroceram 2006, 17:445-450.
85. De Aza P.N., Guitian F., De Aza S. Bioactivity of wollastonite ceramics: in vitro evaluation. Scripta Metall Mater 1994, 31:1001-1005.
86. De Aza P.N., Luklinska Z., Anseau M.R., Guitian F., De Aza S. Morphological studies of pseudowollastonite for biomedical application. J Microsc 1996, 182:24-31.
87. Gou Z., Chang J. Synthesis and in vitro bioactivity of dicalcium silicate powders. J Eur Ceram Soc 2004, 24:93-99.
88. Sun H., Wu C., Dai K., Chang J., Tang T. Proliferation and osteoblastic differentiation of human bone marrow-derived stromal cells on akermanite-bioactive ceramics. Biomaterials 2006, 27:5651-5657.
89. Wu C., Chang J. Degradation, bioactivity, and cytocompatibility of diopside, akermanite, and bredigite ceramics. J Biomed Mater Res B 2007, 83:153-160.
90. 4) bioceramics. Ceram Int 2007, 33:83-88.
91. Kharaziha M., Fathi M.H. Synthesis and characterization of bioactive forsterite nanopowder. Ceram Int 2009, 35:2449-2454.
92. Cromme P., Scheffler M., Greil P. Ceramic tapes from preceramic polymers. Adv Eng Mater 2002, 4:873-877.
93. Bernardo E., Colombo P., Dainese E., Lucchetta G., Bariani P.F. Novel 3D wollastonite-based scaffolds from preceramic polymers containing micro- and nano-sized reactive particles. Adv Eng Mater 2012, 14:269-274.
94. 5:Tb phosphor particles prepared by high temperature spray pyrolysis. Ceram Int 2006, 32:865-870.
95. Zhang Q.Y., Pita K., Buddhudu S., Kam C.H. Luminescent properties of rare-earth ion doped yttrium silicate thin film phosphors for a full-colour display. J Phys D Appl Phys 2002, 35:3085-3090.
96. Qin X., Ju Y., Bernhard S., Yao N. Europium-doped yttrium silicate nano-phosphors prepared by flame pyrolysis. Mater Res Bull 2007, 42:1440-1449.
97. Wu C., Chang J., Zhai W. A novel hardystonite bioceramic: preparation and characteristics. Ceram Int 2005, 31:27-31.
98. Wang G, Lu Z, Dwarte D, Zreiqat H. Porous scaffolds with tailored reactivity modulate in-vitro osteoblast responses. Mater Sci Eng C, doi:10.1016/j.msec.2012.04.068.
99. Yao S., Xue L., Yan Y., Preparation Yan M. Luminescence property of red-emitting hardystonite phosphors by near-ultraviolet irradiation. J Am Ceram Soc 2011, 94:1477-1482.
100. 2+ (M=Ba, Sr, Ca). J Lumin 2007, 122-123:158-161.