Title of article
First-principles calculations of elastic and thermodynamic properties of the four main intermetallic phases in Al–Zn–Mg–Cu alloys
Author/Authors
Li، نويسنده , , C.M. and Zeng، نويسنده , , S.M. and Chen، نويسنده , , Z.Q. and Cheng، نويسنده , , N.P. and Chen، نويسنده , , T.X.، نويسنده ,
Issue Information
روزنامه با شماره پیاپی سال 2014
Pages
11
From page
210
To page
220
Abstract
First-principles calculations are performed to investigate the structural, elastic, and thermodynamic properties of the four main intermetallic phases, namely, MgZn2, Al2CuMg, Al2Cu, and Al3Zr, in Al–Zn–Mg–Cu alloys. The calculated lattice parameters agree with experimental and theoretical values. The formation enthalpy (ΔH) decreases in the order Al3Zr > MgZn2 > Al2CuMg > Al2Cu, whereas the binding energy (Eb) decreases in the order Al3Zr > Al2Cu > Al2CuMg > MgZn2. The calculated result is in accordance with the experimental phenomena. The elastic constants Cij, aggregate elastic modulus (B, G, E), Poisson’s ratio, elastic anisotropy, and Debye temperature have been calculated. The calculated intermetallic phases exhibit elastic anisotropy on the basis of the universal elastic anisotropy index AU. According to the critical values for B/G and Poisson’s ratio, MgZn2 is a ductile phase, whereas Al2CuMg, Al2Cu, and Al3Zr are brittle phases. The Debye temperature decreases in the order Al3Zr > Al2CuMg > Al2Cu > MgZn2. The electronic structures have been investigated based on band structures and density of states. Metallic bonding mode coexists with a fractional ionic interaction in MgZn2, Al2CuMg, and Al2Cu. In Al3Zr, metallic bond coexists with covalent interaction. The temperature and pressure dependencies of volume, heat capacity, and thermal expansion coefficient are investigated systematically in pressures ranging from 0 GPa to 20 GPa and at temperatures ranging from 0 K to 900 K.
Keywords
Thermodynamics properties , First-Principles Calculations , Intermetallic phases , elastic constants
Journal title
Computational Materials Science
Serial Year
2014
Journal title
Computational Materials Science
Record number
1693207
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