Thermodynamics of the Flexible Metal-Organic Framework Material MIL-53(Cr) From First-Principles

We use first-principles density functional theory total energy and linear response phonon calculations to compute the Helmholtz and Gibbs free energy as a function of temperature, pressure, and cell volume in the flexible metal-organic framework material MIL-53(Cr) within the quasiharmonic approximation. GGA and metaGGA calculations were performed, each including empirical van der Waals (vdW) forces under the D2, D3, or D3(BJ) parametrizations. At all temperatures up to 500 K and pressures from -30 to 30 MPa, two minima in the free energy versus volume are found, corresponding to the narrow pore (np) and large pore (lp) structures. Critical positive and negative pressures are identified, beyond which there is only one free energy minimum. While all results overestimated the stability of the np phase relative to the lp phase, the best overall agreement with experiment is found for the metaGGA PBEsol +RTPSS+U+J approach with D3 or D3(BJ) vdW forces. For these parametrizations, the calculated free energy barrier for the np-lp transition is only 3-6 kJ per mole of Cr-4(OH)(4)(C8H4O4)(4).