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Abstract
Covalent organic frameworks (COFs), with their modular architectures and tunable functionalities, provide a versatile platform to design sorbents for direct capture of CO2 from air. Here, we combined density functional theory, molecular dynamics and grand canonical Monte Carlo simulations with experiment to understand structural factors for furthering COF-999-NH2’s performance as the precursor to COF-999 for direct air CO2 capture. Small energy differences among laterally shifted stackings reveal intrinsic stacking heterogeneity. The simulations show pronounced layer buckling coupled to extensive amine–nitrile hydrogen bonding and persistent pore water, which initiates undesired polymerization and undermines uptake. The predicted presence of water is confirmed by subsequent experiments. These insights point to a single, actionable design rule: exclude retained water by introducing hydrophobic pore environments to maximize CO2 capture efficiency.
Supplementary materials
Title
Supporting Information
Description
Additional figures for simulated PXRD patterns compared with experiment; structural properties and stacking energetics from DFT; force field parameters used in Monte Carlo simulations; N2 adsorption isotherms and hydration-dependent structural analysis of thermally relaxed AA models; breakthrough profiles; and further details on the computational assessment of COF-999-NH2.
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