Preparation of high open porosity ceramic foams via direct foaming molded and dried at room temperature

Journal of the European Ceramic Society

Volumn 34, Issue 10, 2014, Pages 2443-2452

  Zhang, Li yuan ^a   Zhou, Da li ^a   Chen, Ying ^a   Liang, Bin ^a   Zhou, Jia bei ^a  

^a SICHUAN UNIVERSITY   (China)

Author keywords

Alpha tricalcium phosphate; Direct foaming; Hydrophobic activated carbon powder; Room temperature drying

Indexed keywords

ACTIVATED CARBON; ALUMINA; COMPRESSIVE STRENGTH; CURING; HYDROPHOBICITY; POROSITY; RAW MATERIALS;

ACTIVATED CARBON POWDER; ANIMAL PROTEINS; CALCINATION TEMPERATURE; CATALYSTS SUPPORT; CRYSTAL PHASIS; DIRECT FOAMING; ROOM TEMPERATURE; STABILIZING AGENTS;

CERAMIC FOAMS;

EID: 84899113679     PISSN: 09552219     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.jeurceramsoc.2014.02.001     Document Type: Article

References (31)

1. Ciambelli P., Palma V., Palo E. Comparison of ceramic honeycomb monolith and foam as Ni catalyst carrier for methane autothermal reforming. Catal Today 2010, 155:92-100.
2. Zuercher S., Pabst K., Schaub G. Ceramic foams as structured catalyst inserts in gas-particle filters for gas reactions-effect of backmixing. Appl Catal A Gen 2009, 357:85-92.
3. Krauss Juillerat F., Engeli R., Jerjen I., et al. Synthesis of bone-like structured foams. J Eur Ceram Soc 2013, 33:1497-1505.
4. Jana P., Ganesan V. Processing of low-density alumina foam. J Eur Ceram Soc 2011, 31:75-78.
5. Min W., Du H.Y., Guo A.R., Hao R.H., Hou Z.G. Microstructure control in ceramic foams via mixed cationic/anionic surfactant. Mater Lett 2012, 88:97-100.
6. Kima H., Leeb S., Hanc Y., Parkc J. Control of pore size in ceramic foams: influence of surfactant concentration. Mater Chem Phys 2009, 113:441-444.
7. Medri V., Ruffini A. The influence of process parameters on in situ inorganic foaming of alkali-bonded SiC based foams. Ceram Int 2012, 38:3351-3359.
8. 4 ceramic foams. Mater Lett 2011, 65:1801-1804.
9. Akpinara S., Kusoglu I.M., Ertugrul O., One K. Silicon carbide particle reinforced mullite composite foams. Ceram Int 2012, 38:6163-6169.
10. 4 ceramic foams by simultaneously using egg white protein and fish collagen. Ceram Int 2013, 39:445-448.
11. Juettner T., Moertel H., Svinka V., Svinka R. Structure of kaoline-alumina based foam ceramics for high temperature applications. J Eur Ceram Soc 2007, 27:1435-1441.
12. Shao Y.F., Jia D.C., Liu B.Y. Characterization of porous silicon nitride ceramics by pressureless sintering using fly ash cenosphere as a pore-forming agent. J Eur Ceram Soc 2009, 29:1529-1534.
13. Fukasawa T., Deng Z.Y., Ando M., Ohji T., Goto Y. Pore structure of porous ceramics synthesized from water-based slurry by freeze-dry process. J Mater Sci 2001, 36:2523-2527.
14. Li D.Y., Li M.S. Preparation of porous alumina ceramic with ultra-high porosity and long straight pores by freeze casting. J Porous Mater 2012, 19:345-349.
15. Lin Y.M., Li C.W., Wang C.A. Effects of mullite content on the properties and microstructure of porous anorthite/mullite composite ceramics. J Inorg Mater 2011, 26:1095-1100.
16. He X., Tang Z.H., Zhu Y.F., Yang J.H. Fabrication of carbon foams with low thermal conductivity using the protein foaming method. Mater Lett 2013, 94:55-57.
17. Oboroceanu D., Wang L., Magner E., Auty M.A.E. Fibrillization of whey proteins improves foaming capacity and foam stability at low protein concentrations. J Food Eng 2014, 121:102-111.
18. Remadnia A., Dheilly R.M., Laidoudi B., Quéneudec M. Use of animal proteins as foaming agent in cementitious concrete composites manufactured with recycled PET aggregates. Constr Build Mater 2009, 23:3118-3123.
19. Vivaldini D.O., Luz A.P., Salvinin V.R., Pandolfelli V.C. Why foams containing colloidal hydrophilic particles are unstable. Ceram Int 2013, 39:6005-6008.
20. Binks B., Horozov T. Aqueous foams stabilized solely by silica nanoparticles. Angew Chem 2005, 117:3788-3791.
21. Mishra S., Mitra R., Vijayakumar M. Processing and microstructure of particle stabilized silica foams. Mater Lett 2009, 63:2649-2651.
22. Yang W.Z., Zhou D.L., Yin S.Y., Yin G.F., Gao L.D., Zhang Y. Osteogenesis capacity of a novel BMP/α-TCP bioactive composite bone cement. J Wuhan Univ Technol-Mater Sci Ed. 2004, 19:30-34.
23. Rodrigues Neto J.B., Moreno R. Rheological behaviour of kaolin/talc/alumina suspensions for manufacturing cordierite foams. Appl Clay Sci 2007, 37:157-166.
24. Pradhan M., Bhargava P. Defect and microstructural evolution during drying of soapnut-based alumina foams. J Eur Ceram Soc 2008, 28:3049-3057.
25. Ozbayoglu M.E., Kuru E., Miska S., Takach N. A comparative study of hydraulic models for foam drilling. Society of Petroleum Engineers 2000, 65487.
26. Koehler S.A., Stone H.A., Brenner M.P., Eggers J. Dynamics of foam drainage. Am Phys Soc 1998, 58:2097-2106.
27. Chen X.J., Lu A.X., Qu G. Preparation and characterization of foam ceramics from red mud and fly ash using sodium silicate as foaming agent. Ceram Int 2013, 39:1923-1929.
28. Holmes D.M., Kumar R.V., Clegg W.J. Cracking during lateral drying of alumina suspensions. J Am Ceram Soc 2006, 89:1908-1913.
29. Lan W., Xiao P. Constrained drying of aqueous yttria-stabilized zirconia slurry on a substrate. I: Drying mechanism. J Am Ceram Soc 2006, 89:1518-1522.
30. Prud'homme E., Michaud P., Joussein E., Peyratout C., Smith A., Rossignol S. In situ inorganic foams prepared from various clays at low temperature. Appl Clay Sci 2011, 51:15-22.
31. Castelein O., Guinebretière R., Bonnet J.P., Blanchart P. Shape, size and composition of mullite nanocrystals from a rapidly sintered kaolin. J Eur Ceram Soc 2001, 21:2369-2376.