Ultrasonic determination of the temperature and hydrostatic pressure dependences of the elastic properties of ceramic titanium diboride

Citation
Sp. Dodd et al., Ultrasonic determination of the temperature and hydrostatic pressure dependences of the elastic properties of ceramic titanium diboride, J MATER SCI, 36(16), 2001, pp. 3989-3996
Citations number
40
Categorie Soggetti
Apllied Physucs/Condensed Matter/Materiales Science","Material Science & Engineering
Journal title
JOURNAL OF MATERIALS SCIENCE
ISSN journal
00222461 → ACNP
Volume
36
Issue
16
Year of publication
2001
Pages
3989 - 3996
Database
ISI
SICI code
0022-2461(200108)36:16<3989:UDOTTA>2.0.ZU;2-6
Abstract
Pulse-echo-overlap measurements of ultrasonic wave velocity have been used to determine the elastic stiffness moduli and related elastic properties of titanium diboride (TiB2) ceramic samples as functions of temperature in th e range 130-295 K and hydrostatic pressure up to 0.2 GPa at room temperatur e. TiB2 is an elastically stiff but light ceramic: at 295 K, the longitudin al stiffness (C-L), shear stiffness (mu), adiabatic bulk modulus (B-S), You ng's modulus (E) and Poisson's ratio (sigma) are 612 GPa, 252 GPa, 276 GPa, 579 GPa and 0.151, respectively. The adiabatic bulk modulus B-S is in good agreement with the results of recent theoretical calculations. All elastic moduli increase with decreasing temperature and do not show any pronounced unusual effects. The results of measurements of the effects of hydrostatic pressure on the ultrasonic wave velocity have been used to determine the h ydrostatic-pressure derivatives of elastic stiffnesses and the acoustic-mod e Gruneisen parameters. The values determined at 295 K for the hydrostatic- pressure derivatives (partial derivativeC(L)/partial derivativeP)(P=0), (pa rtial derivative mu/partial derivativeP)(P=0) and (partial derivativeB(S)/p artial derivativeP)(P=0) are 7.29 +/- 0.1, 2.53 +/- 0.1 and 3.91 +/- 0.1, r espectively. The hydrostatic-pressure derivative (partial derivativeB(S)/pa rtial derivativeP)(P)=0 of the bulk modulus of TiB2 ceramic is found to be larger than that estimated previously from uniaxial shock-wave loading expe riments. The longitudinal (gamma (L)), shear (gamma (S)), and mean (gamma ( el)) acoustic-mode Gruneisen parameters of TiB2 are positive: the zone-cent re acoustic phonons stiffen under pressure in the usual way. Since the acou stic Debye temperature Theta (D) (=1190 K) is very high, the shear modes pr ovide a substantial contribution to the acoustic phonon population at room temperature. Knowledge of the elastic and nonlinear acoustic properties she ds light on the thermal properties of ceramic TiB2. (C) Kluwer Academic Pub lishers.