Mechanical spectroscopy of grain boundary sliding in ceramics ‒ SCI-SB-DM ‐ EPFL

The mechanical loss associated with GB sliding has been measured by using mechanical spectroscopy. More precisely we have studied zirconia specimens differing from one another by the impurity content (volume fraction of the inter-granular glassy phase), by the grain size and by additions of second phase SiO₂ particles or nano-fibers such as carbon nanotubes. The mechanical loss is the highest in SiO₂ doped 3Y-TZP samples, and so is the creep rate. On the contrary, the high temperature mechanical loss decreases with additions of carbon nanotubes, which can pin the grain boundaries.

When an amorphous phase occurs between grains, often because of the sintering aids, it plays an essential lubricating role in the GB sliding process. On the other hand, it allows high-temperature super-plastic deformation, but it deteriorates the mechanical properties, for instance strength and creep resistance above a certain temperature. When GBs are “clean“, the GB sliding takes place by motion of the intergranular dislocations. In order to inprove the mechanical properties at high-temperature the zirconia and alumina polycrystalline ceramics are doped with singlewalled carbon nanotubes, multiwalled carbon nanotubes, silicon carbide particles or silicon carbide whiskers. The undoped and doped ceramic composites are produced by powder metallurgy. SEM and TEM techniques are used to characterize the microstructure of involved material. The sintered samples are carried out into forced torsion pendula.

Publications (2000-2011)
M. Mazaheri, D. Mari, Z. R. Hesabi, R. Schaller and G. Fantozzi Multi-walled carbon nanotube / nanostructured zirconia composites: Outstanding mechanical properties in a wide range of temperature, Composites Science and Technology (2011) accepted

M. Mazaheri, D. Mari, R. Schaller, G. Bonnefont and G. Fantozzi, Processing of yttria stabilized zirconia reinforced with multi-walled carbon nanotubes with attractive mechanical properties. J. Euro. Cer. Soc. (2011) In Press, published online doi:10.1016/j.jeurceramsoc.2010.11.009

M. Mazaheri, D. Mari, R. Schaller, Y. Cai, S. Esmaeilzadeh, and Z. Shen, High-Temperature Mechanical Spectroscopy of Nitrogen-Rich Ca-α-SiAlON Ceramics. J. Am. Ceram. Soc. (2011) In press, published online doi:10.1111/j.1551-2916.2010.04251.x

M. Mazaheri, D. Mari, R. Schaller, High temperature mechanical spectroscopy of yttria stabilized zirconia reinforced with carbon nanotubes. Phys. Stat. Sol. (a). (2010) 207, 2456-2460

Ionascu C, Schaller R, Influence of carbon nanotubes and silicon carbide whiskers on the mechanical loss due to grain boundary sliding in 3-mol% yttria-stabilized tetragonal zirconia polycrystals. Materials Science and Engineering: A. 2006; 442, 175-178.

M. Daraktchiev, B. Van de Moortèle, R. Schaller, E. Couteau and L. Forró, “Effects of Carbon Nanotubes on Grain Boundary Sliding in Zirconia Polycrystals.”, Adv. Mater. 17, 88-91, (2005).

R. Schaller, M. Daraktchiev and S. Testu “Creep behavior of ceramics studied by mechanical loss measurements.“, Mater. Sci. Eng. A 387-389 , 687-691, (2004).

M. Daraktchiev and R. Schaller, “High temperature mechanical loss behavior of 3 mol% yttria-stabilized tetragonal zirconia polycrystals (3Y-TZP)”, phys. stat. sol.(a) 195, 293-304, (2003).

C. Mayencourt and R. Schaller, “Mechanical-stress relaxation in magnesium-based composites.”, Mat. Sci. Eng. A 325, 286-291, (2002).

M. Daraktchiev and R. Schaller, “Mechanical Loss in 3mol%Yttria-DopedTetragonal Zirconia Polycrystals (3Y-TZP)”, Defect and Diffusion Forum 206-207, 163-167, (2002).

S. Testu and R. Schaller, “Internal Friction Peak in Silicon Nitride Sintered without Additives.”, Defect and Diffusion Forum 206-207, 167-170, (2002).

R. Schaller and M. Daraktchiev, “Mechanical spectroscopy of creep appearance in fine-grained yttria-stabilized zirconia.”, J. European Ceramic Society 22, 2461-2467, (2002).

S. Testu, R. Schaller, J.L. Besson, T. Rouxel and G. Bernard-Granger, “Mechanical spectroscopy connected to creep and stress relaxation in a high resistant silicon nitride.”, J. European Ceramic Society 22 , 2511-2516, (2002).

R. Schaller and A. Lakki, “Grain boundary relaxations in ceramics”, in Mechanical Spectroscopy Q^-1 2001, R. Schaller, G. Fantozzi and G. Gremaud, eds., Mater. Sci. Forum 366-368 (2001) 315-337.

R. Schaller and G. Fantozzi, “Damping and toughness”, in Mechanical Spectroscopy Q^-1 2001, R. Schaller, G. Fantozzi and G. Gremaud, eds., Mater. Sci. Forum 366-368 (2001) 615-620.

R. Schaller, “Mechanical Spectroscopy of the High-Temperature Brittle-to-Ductile Transition in Ceramics and Cermets.”, J. Alloys and Compounds 310, 7-15, (2000).

G. Roebben, L. Donzel, M. Steen, R. Schaller and O. Van der Biest, “Fatigue Resistant Silicon Nitride Ceramics due to Anelastic Deformation and Energy Dissipation.”, J. Alloys and Compounds 310, 39-43, (2000).