Oxidative Dehydrogenative Coupling of Thiols with Alkanes for the Synthesis of Sulfoxides

An oxidative dehydrogenative coupling of thiols with alkanes via direct C(sp³)-H bond functionalization to form a new C-S bond and S═O double bond was developed. The present reaction features the use of readily available reagents and high step- and atom-efficiency, thus providing an efficient access to sulfoxides. A possible mechanism is proposed.

Morphology prediction of 1,3,5,7-tetranitro-1,3,5,7-tetrazocane (HMX) crystal in dimethyl sulfoxide (DMSO) solvent with different models using molecular dynamics simulation

The interface interaction between DMSO solution and HMX crystal was simulated by molecular dynamics (MD) method, and the morphology of HMX in DMSO solvent was predicted through the occupancy model and attachment energy (AE) model. The intramolecular and intermolecular interactions in HMX crystals were dominated by O···H/H···O contacts, accounting for 63.0%. The S value and the adsorption position of DMSO on different crystal planes of HMX have been compared, which showed that (1 0 - 1) has a deep cavity for the adsorption of solvent molecules. The density of DMSO in the z direction of the different planes showed that (0 1 1) has the largest density peak and (0 2 0) has the smallest density peak. The DMSO solvent had an attraction effect with each crystal plane of HMX. The absolute value of E_int was sorted as follows: (1 1 0) > (1 0 1) > (0 2 0) > (1 0 - 1) > (0 1 1). The DMSO solvent affected the attachment energy of each crystal plane of HMX. In our simulation system, the prediction results of the occupancy model were the most consistent with the experimental values.

Binary mixtures of novel sulfoxides and water: intermolecular structure, dynamic properties, thermodynamics, and cluster analysis

Higher molecular weight dialkyl sulfoxides attract interest in the context of biomedical sciences due to their ability to penetrate phospholipid bilayers, dissolve drugs, and serve as cryoprotectants. Intermolecular interactions with water, a paramount component of the living cell, determine the performance of the sulfoxide-based artificial systems in their prospective applications. Herein, we simulated a wide composition range of sulfoxide/water mixtures, up to 85 w/w% sulfoxide, using classical molecular dynamics to determine structure, dynamics, and thermodynamics as a function of the mixture composition. As found, both diethyl sulfoxide (DESO) and ethyl methyl sulfoxide (EMSO) are strongly miscible with water. DESO- and EMSO-based aqueous mixtures exhibit similar structure and thermodynamic properties, however, quite different dynamic properties over the entire range of compositions. Strong deviations from an ideal mixture of between 30-50 mol% (based on molar volume) of sulfoxide content lead to relatively high dynamic viscosities of the mixtures. The free energy of mixing with water is only slightly more favorable for EMSO than for DESO. The results, for the first time, quantify high miscibilities of both sulfoxides with water and motivate comprehensive in vivo investigation of the proposed mixtures.

Liquid structure of dibutyl sulfoxide

Liquid DBSO shows mesoscopic polar/apolar alternation. Dipole–dipole interactions are responsible for correlations between DBSO molecules that do not interact through hydrogen bonding.