Quantifying Mechanical Properties of Molecular Crystals: A Critical Overview of Experimental Elastic Tensors.

This review presents a critical and comprehensive overview of current experimental measurements of complete elastic constant tensors for molecular crystals. For a large fraction of these molecular crystals detailed comparisons are made with elastic tensors obtained using the corrected small basis set Hartree-Fock method S-HF-3c, and these are shown to be competitive with many of those obtained from more sophisticated density functional theory plus dispersion (DFTD) approaches. These detailed comparisons between S-HF3c, experimental and DFT-D computed tensors make use of a novel rotation-invariant spherical harmonic description of the Young's modulus, and identify outliers among sets of independent experimental results. The result is a curated database of experimental elastic tensors for molecular crystals, which we hope will stimulate more extensive use of elastic tensor information - experimental and computational - in studies aimed at correlating mechanical properties of molecular crystals with their underlying crystal structure. This is particularly relevant in current studies that exploit techniques such as nanoindentation and micro-focused mapping experiments on bent crystals.