Monte Carlo Simulations of Water Adsorption in Aluminum Oxide Rod-Based Metal-Organic Frameworks

Atmospheric water harvesting utilizing nanoporous sorbent materials with suitable adsorption characteristics has recently emerged as a potential solution for the global water crisis. Here, we probe the adsorption behavior of two high performing Al(mu 2-OH) rod-based metal-organic frameworks (MOFs), MOF-303 and MOF-333, using Gibbs ensemble Monte Carlo simulations. We find that simulations using nonpolarizable force fields and rigid framework structures optimized using periodic electronic structure calculations can achieve good agreement with experimental data for adsorption isotherms and isosteric heats of adsorption; however, for MOF-303, it is important to utilize a structure that accounts for the distortion associated with water adsorbed at the primary adsorption site.

Automated summary

Atmospheric water harvesting using nanoporous sorbent materials has emerged as a potential solution for global water crisis. This study investigates the adsorption behavior of two high-performing metal-organic frameworks (MOFs), MOF-303 and MOF-333, through simulation. The results show that simulations with nonpolarizable force fields and rigid framework structures optimized using electronic structure calculations can achieve good agreement with experimental data, but for MOF-303, a structure accounting for the distortion associated with adsorbed water is necessary.