Interaction of Polymer of Intrinsic Microporosity PIM-1 with explosive analytes at the molecular level: Combined experiment and computational modelling

TL;DR

This study combines experimental spectroscopy and computational modeling to understand how PIM-1 polymer interacts with explosive nitroaromatic molecules, revealing molecular binding mechanisms relevant for sensor development.

Contribution

It provides detailed molecular-level insights into PIM-1's interactions with explosives, combining spectroscopy with electronic-structure calculations to inform sensor design.

Findings

PIM-1 interacts strongly with nitroaromatic explosives altering electronic energy levels.

Binding involves multiple polymer repeat units forming a pocket for analytes.

Experimental and theoretical results agree, validating the interaction mechanisms.

Abstract

This work investigates the molecular-level interactions of a fluorescent microporous polymer (PIM-1) with nitroaromatic explosives, in the context of thin film explosive sensors. Thin films of the PIM-1 were exposed to 2,4-dinitrotoluene (DNT) and 2,4,6-trinitrotoluene (TNT), and their steady-state absorption and emission spectra measured. For comparison, the response of PIM-1 to non-explosive molecules such as benzene (BN) was also explored. Complementary electronic-structure calculations were used to predict absorption and emission spectra and to determine binding energies for the PIM-1-analyte complexes. The calculations agree well with experiment and reveal that association of nitroaromatic analyte molecules with PIM-1 alters the energy levels and the arrangements of frontier orbitals, indicating significant molecular interactions. Calculations show that the electronic properties and photo-excited electron transfer can be described by interaction with a single repeat unit of the polymer. The molecular binding, however, involves interaction with at least three repeat units, with the DNT or TNT molecule binding into a pocket in the contorted structure of the microporous polymer. Together, the experimental and theoretical results demonstrate that PIM-1 is a promising platform for selective nitroaromatic detection and provide molecular design principles that could improve sensitivity and selectivity in future sensor materials.