IR spectroscopy of small and weakly interacting molecular probes for acidic and basic zeolites

Abstract

The application of small and weakly interacting probe molecules for the characterization of acidic and basic properties by FTIR spectroscopy is exemplified by using H- and alkali cation-exchanged zeolites as typical solid Brönsted and Lewis acids and Lewis bases. Criteria for the selection of probe molecules are given. Brönsted acidity can be characterized by the H-bonding method when CO and N₂ are used as molecular probes. Quantum chemical calculations are shown to provide important additional information on the electronic nature of the adsorption interaction and the vibrational behaviour of the probe molecule. Lewis acidity dominates in cation-exchanged zeolites for small cations (Li⁺, Na⁺) whereas basic properties develop with increasing cation radius. CO, CO₂, N₂ and CH₄ interact with cation centers, the interaction energy decreasing with increasing cation radius. CO at very low equilibrium pressures permits a siting of Na⁺, and the Al distribution in six-rings (S_II-sites) can be probed. CH₄ interacts with cations in the M⁺···H₃CH configuration having C_3v symmetry. CH-acids such as Cl₃CH(D), acetylene and methylacetylene, are shown to be potentially suitable probe molecules for basic properties using the H-bonding method. All three molecules undergo O_z ²⁻···H–C H-bonding and the induced red-shift of the C–H stretching frequency permits a ranking of the base strength of a given series of materials.