Δ9-Tetrahydrocannabinol (THC) is the principal psychoactive
component of cannabis, and there is an urgent need to build low-cost
and portable devices that can detect its presence from breath. Similarly
to alcohol detectors, these tools can be used by law enforcement to
determine driver intoxication and enforce safer and more regulated
use of cannabis. In this work, we propose to use a class of microporous
crystals, metal–organic frameworks (MOFs), to selectively adsorb
THC that can be later detected using optical, electrochemical, or
fluorescence-based sensing methods. We computationally screened more
than 5000 MOFs, highlighting the materials that have the largest affinity
with THC, as well as the highest selectivity against water, showing
that it is thermodynamically feasible for MOFs to adsorb THC from
humid breath. We propose and compare different models for THC and
different computational protocols to rank the promising materials,
also presenting a novel approach to assess the permeability of a porous
framework to nonspherical molecules. We identified three adsorption
motifs in MOFs with high affinity to THC, which we refer to as “narrow
channels”, “thick walls”, and “parking
spots”. Therefore, we expect our protocols and our findings
to be generalizable for different classes of microporous materials
and also for investigating the adsorption properties of other large
molecules that, like THC, have a nonspherical shape.