ELATooLs: A tool for analyzing anisotropic elastic properties of the 2D and 3D materials

We introduce a computational method and a user-friendly code with a terminal-based graphical user interface (GUI), named ELATooLs, developed to analyze mechanical and anisotropic elastic properties. ELATooLs enables facile analysis of the second-order elastic stiffness tensor of two-dimensional (2D) and three-dimensional (3D) crystal systems. It computes and displays the main mechanical properties including the bulk modulus, Young's modulus, shear modulus, hardness, p-wave modulus, universal anisotropy index, Chung-Buessem anisotropy index, log-Euclidean anisotropy parameter, Cauchy pressures, Poisson's ratio, and Pugh's ratio, using three averaging schemes of Voigt, Reuss, and Hill. It includes an online and offline database from the Materials Project with more than 13,000 elastic stiffness constants for 3D materials. The program supports output files of the well-known computational codes IRelast, IRelast2D, ElaStic, and AELAS. Four types of plotting and visualization tools are integrated to conveniently interface with GNUPLOT, XMGRACE, view3dscene and plotly libraries, offering immediate post-processing of the results. ELATooLs provides reliable means to investigate the mechanical stability based on the calculation of six (three) eigenvalues of the elastic tensor in 3D (2D) materials. It can efficiently identify anomalous mechanical properties, such as negative linear compressibility, negative Poisson's ratio, and highly-anisotropic elastic modulus in 2D and 3D materials, which are central properties to design and develop high-performance nanoscale electromechanical devices. Moreover, ELATooLs can predict the behavior of the sound velocities and their anisotropic properties, such as acoustic phase/group velocities and power flow angles in materials, by solving the Christoffel equation. Six case studies on selected material systems, namely, ZnAu2 (CN)(4), CrB2, delta-phosphorene, Pd2O6Se2 monolayer, and GaAs, and a hypothetical set of systems with cubic symmetry are presented to demonstrate the descriptive and predictive capabilities of ELATooLs. Program summary Title: ELATooLs Licensing provisions: GNU General Public Licence 3.0 Nature of the problem: Identifying anisotropic elastic properties of 2D and 3D materials, and calculating acoustic phase and group velocities in homogeneous solids. Solution method: Second-order elastic stiffness tensor analysis using transformation law and calculations of the elastic surfaces properties. Solving the Christoffel equation eigenvalue problem using diagonalization and calculations of the sound velocities. Programming language: Fortran 90 Operating system: Unix/Linux/MacOS/Windows by Cygwin: http: //www.cygwm.com/ Distribution format: tar.gz Required routines/libraries: LAPACK, BLAB, and Plotly Javascript libraries, GNUPLOT, XMGRACE, view3dscene. Computer: Any system with a Fortran 90 (F90) compiler Memory: Up to 1 GB for any symmetry Run time: Up to 70 seconds for any symmetry, and (400x400) = (theta x phi)-mesh in spherical coordinate Documentation: Available at https: //yalameha.gitlab.io/elastictools/index.html (C) 2021 Elsevier B.V. All rights reserved.