Sol M. Mejía scite author profile

Using a grid-based method to search the critical points in electron density, we show how to accelerate such a method with graphics processing units (GPUs). When the GPU implementation is contrasted with that used on central processing units (CPUs), we found a large difference between the time elapsed by both implementations: the smallest time is observed when GPUs are used. We tested two GPUs, one related with video games and other used for high-performance computing (HPC). By the side of the CPUs, two processors were tested, one used in common personal computers and other used for HPC, both of last generation. Although our parallel algorithm scales quite well on CPUs, the same implementation on GPUs runs around 10× faster than 16 CPUs, with any of the tested GPUs and CPUs. We have found what one GPU dedicated for video games can be used without any problem for our application, delivering a remarkable performance, in fact; this GPU competes against one HPC GPU, in particular when single-precision is used.

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Cooperative effects on the structure and stability of (ethanol)3–water, (methanol)3–water heterotetramers and (ethanol)4, (methanol)4 tetramers

Mejía¹,

Espinal²,

Mondragón³

2009

Journal of Molecular Structure: THEOCHEM

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Molecular Interaction of (Ethanol)₂−Water Heterotrimers

et al. 2007

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The potential energy surface of the (ethanol)2-water heterotrimers for the trans and gauche conformers of ethanol was studied using density functional theory. The same approximation was used for characterizing representative clusters of (ethanol)3, (methanol)3, and (methanol)2-water. Trimerization energies and enthalpies as well as the analysis of geometric parameters suggest that the structures with a cyclic pattern in the three hydrogen bonds of the type O-H---O (primary hydrogen bonds), where all molecules are proton donor-acceptor at the same time, are more stable than those with just two primary hydrogen bonds. Additionally, we propose the formation of "secondary hydrogen bonds" between hydrogen atoms of the methyl group of ethanol and the oxygen atom of water or other ethanol molecule (C-H---O), which were found to be weaker than the primary hydrogen bonds.

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The role of OH…O and CH…O hydrogen bonds and H…H interactions in ethanol/methanol–water heterohexamers

et al. 2016

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Bioethanol is one of the world's most extensively produced biofuels. However, it is difficult to purify due to the formation of the ethanol-water azeotrope. Knowledge of the azeotrope structure at the molecular level can help to improve existing purification methods. In order to achieve a better understanding of this azeotrope structure, the characterization of (ethanol)5-water heterohexamers was carried out by analyzing the results of electronic structure calculations performed at the B3LYP/6-31+G(d) level. Hexamerization energies were found to range between -36.8 and -25.8 kcal/mol. Topological analysis of the electron density confirmed the existence of primary (OH…O) hydrogen bonds (HBs), secondary (CH…O) HBs, and H…H interactions in these clusters. Comparison with three different solvated alcohol systems featuring the same types of atom-atom interactions permitted the following order of stability to be determined: (methanol)5-water > (methanol)6 > (ethanol)5-water > (ethanol)6. These findings, together with accompanying geometric and spectroscopic analyses, show that similar cooperative effects exist among the primary HBs for structures with the same arrangement of primary HBs, regardless of the nature of the molecules involved. This result provides an indication that the molecular ratio can be considered to determine the unusual behavior of the ethanol-water system. The investigation also highlights the presence of several types of weak interaction in addition to primary HBs. Graphical Abstract Water-ethanol clusters exhibit a variety of interaction types between their atoms, such as primary OH...O (blue), secondary CH...O (green) and H...H (yellow) interactions as revealed by Quantum Chemical Topology.

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Sol M. Mejía

Grid‐based algorithm to search critical points, in the electron density, accelerated by graphics processing units

Cooperative effects on the structure and stability of (ethanol)3–water, (methanol)3–water heterotetramers and (ethanol)4, (methanol)4 tetramers

Molecular Interaction of (Ethanol)₂−Water Heterotrimers

The role of OH…O and CH…O hydrogen bonds and H…H interactions in ethanol/methanol–water heterohexamers

Contact Info

Product

Resources

About

Sol M. Mejía

Grid‐based algorithm to search critical points, in the electron density, accelerated by graphics processing units

Cooperative effects on the structure and stability of (ethanol)3–water, (methanol)3–water heterotetramers and (ethanol)4, (methanol)4 tetramers

Molecular Interaction of (Ethanol)2−Water Heterotrimers

The role of OH…O and CH…O hydrogen bonds and H…H interactions in ethanol/methanol–water heterohexamers

Contact Info

Product

Resources

About

Molecular Interaction of (Ethanol)₂−Water Heterotrimers