Accommodation, Accumulation, and Migration of Defects in Ti3SiC2 and Ti3AlC2 MAX Phases
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In: Journal of American Ceramic Society, Vol. 96, No. 10, 01.10.2013, p. 3196-3201.
Research output: Contribution to journal › Article › peer-review
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T1 - Accommodation, Accumulation, and Migration of Defects in Ti3SiC2 and Ti3AlC2 MAX Phases
AU - Middleburgh, Simon C.
AU - Lumpkin, Greg R.
AU - Riley, Daniel
PY - 2013/10/1
Y1 - 2013/10/1
N2 - We have determined the energetics of defect formation and migration in M(n+1)AX(n) phases with M=Ti, A=Si or Al, X=C, and n=3 using density functional theory calculations. In the Ti3SiC2 structure, the resulting Frenkel defect formation energies are 6.5eV for Ti, 2.6eV for Si, and 2.9eV for C. All three interstitial species reside within the Si layer of the structure, the C interstitial in particular is coordinated to three Si atoms in a triangular configuration (C-Si=1.889 angstrom) and to two apical Ti atoms (C-Ti=2.057 angstrom). This carbon-metal bonding is typical of the bonding in the SiC and TiC binary carbides. Antisite defects were also considered, giving formation energies of 4.1eV for Ti-Si, 17.3eV for Ti-C, and 6.1eV for Si-C. Broadly similar behavior was found for Frenkel and antisite defect energies in the Ti3AlC2 structure, with interstitial atoms preferentially lying in the analogous Al layer. Although the population of residual defects in both structures is expected to be dominated by C interstitials, the defect migration and Frenkel recombination mechanism in Ti3AlC2 is different and the energy is lower compared with the Ti3SiC2 structure. This effect, together with the observation of a stable C interstitial defect coordinated by three silicon species and two titanium species in Ti3SiC2, will have important implications for radiation damage response in these materials.
AB - We have determined the energetics of defect formation and migration in M(n+1)AX(n) phases with M=Ti, A=Si or Al, X=C, and n=3 using density functional theory calculations. In the Ti3SiC2 structure, the resulting Frenkel defect formation energies are 6.5eV for Ti, 2.6eV for Si, and 2.9eV for C. All three interstitial species reside within the Si layer of the structure, the C interstitial in particular is coordinated to three Si atoms in a triangular configuration (C-Si=1.889 angstrom) and to two apical Ti atoms (C-Ti=2.057 angstrom). This carbon-metal bonding is typical of the bonding in the SiC and TiC binary carbides. Antisite defects were also considered, giving formation energies of 4.1eV for Ti-Si, 17.3eV for Ti-C, and 6.1eV for Si-C. Broadly similar behavior was found for Frenkel and antisite defect energies in the Ti3AlC2 structure, with interstitial atoms preferentially lying in the analogous Al layer. Although the population of residual defects in both structures is expected to be dominated by C interstitials, the defect migration and Frenkel recombination mechanism in Ti3AlC2 is different and the energy is lower compared with the Ti3SiC2 structure. This effect, together with the observation of a stable C interstitial defect coordinated by three silicon species and two titanium species in Ti3SiC2, will have important implications for radiation damage response in these materials.
U2 - 10.1111/jace.12537
DO - 10.1111/jace.12537
M3 - Erthygl
VL - 96
SP - 3196
EP - 3201
JO - Journal of American Ceramic Society
JF - Journal of American Ceramic Society
SN - 0002-7820
IS - 10
ER -