Tyler R. Josephson

Origin of 5‐Hydroxymethylfurfural Stability in Water/Dimethyl Sulfoxide Mixtures

In the present work, we combined vibrational spectroscopy with electronic structure calculations to understand the solvation of HMF in DMSO, water, and DMSO/water mixtures and to provide insights into the observed hindrance of HMF rehydration and aldol condensation reactions if it is dissolved in DMSO/water mixtures. To achieve this goal, the attenuated total reflection FTIR spectra of a wide composition range of binary and ternary mixtures were measured, analyzed, and compared to the findings of ab initio DFT calculations. The effect of solvent on the HMF C-O and O-H vibrational modes reveals significant differences that are ascribed to different intermolecular interactions between HMF and DMSO or water. We also found that DMSO binds to HMF more strongly than water, and interactions with the HMF hydroxyl group are stronger than those with the HMF carbonyl group. We also showed the preferential solvation of HMF C-O groups by DMSO if HMF is dissolved in DMSO/water mixed solvent. Frontier molecular orbital theory was used to examine the influence of the solvent on side reactions. The results show that HMF solvation by DMSO increases its LUMO energy, which reduces its susceptibility to nucleophilic attack and minimizes undesirable hydration and humin-formation reactions. This result, together with the preferential solvation of HMF by DMSO, provide an explanation for the enhanced HMF stability in DMSO/water mixtures observed experimentally.

Solvent-Induced Frequency Shifts of 5-Hydroxymethylfurfural Deduced via Infrared Spectroscopy and ab Initio Calculations

Solvent-induced frequency shifts (SIFS) of the carbonyl stretching vibration ν(C═O) of 5-hydroxymethylfurfural were measured in protic, polar aprotic, and nonpolar solvents. The Gutmann acceptor number (AN) was found to correlate with the measured frequency shifts. The SIFS in six solvents were investigated using ab initio electronic structure calculations, treating the solvent implicitly and with an explicit solvent ligand interacting with the carbonyl. The conductor-polarizable continuum model (CPCM) of solvation predicted that ν(C═O) shifted according with the dielectric constant as (ε - 1)/(2ε + 1), in agreement with the analytical predictions of the Kirkwood-Bauer-Magat (KBM) theory for a dipole in a dielectric continuum, but in disagreement with the experimental trend. The experimental SIFS were best predicted using gas-phase complexes of HMF and explicit solvent-ligand. Natural bond orbital (NBO) analysis and Baders atoms in molecules theory were used to investigate the electronic structure of these complexes. Strong SIFS were found to arise from stronger H-bonding interactions, as observed in delocalization of carbonyl lone-pair electrons by H-bonding solvent σ*(X-H) orbitals, and an increase in charge density and a decrease in local potential energy at the H-bond (3, -1) critical point. Consequently, by predicting the experimental SIFS and examining the electronic structure, we find the first theoretical evidence for treating Gutmanns solvent AN as a measure of solvent Lewis acidity.

Monte Carlo simulations probing the liquid/vapour interface of water/hexane mixtures: adsorption thermodynamics, hydrophobic effect, and structural analysis

ABSTRACT Knowledge about the interfacial properties of water/oil mixtures is important for the petrochemical industry and for understanding detergency and hydrophobic effects. Here, we probe the liquid/vapour interface of water/n-hexane mixtures using configurational-bias Monte Carlo simulations in the osmotic Gibbs ensemble. We study the effect of n-hexane at several partial pressures ranging from 25% to 95% of its saturated vapour pressure and observe that the surface tension decreases with increasing n-hexane pressure. Additionally, we analyse the simulation trajectories to provide molecular-level insights on the spatial distribution of n-hexane and the structure of the interface. The n-hexane molecules strongly adsorb from the vapour phase onto the liquid interface with a preferentially parallel orientation with respect to the interface. The surface excess, from the Gibbs adsorption isotherm equation, is calculated and used to systematically define the domain of adsorbed n-hexane. Integrating over this gives the free energy of adsorption of n-hexane, which is highly favourable, varying from to  kJ/mol as the partial pressure of n-hexane is increased. The enrichment of n-hexane molecules on the interface yields a positive deviation from Henrys law at higher partial pressures, providing evidence for favourable adsorbate-adsorbate interactions. GRAPHICAL ABSTRACT