Dispersion-correcting potentials can significantly improve the bond dissociation enthalpies and noncovalent binding energies predicted by density-functional theory

Although anisyl units are basically poor ligands for metal ions, the rigid placements of their oxygens during synthesis rather than during complexation are undoubtedly responsible for the enhanced binding and selectivity of the spherand. We used standard B3LYP/6-31G** (5d) density functional theory (DFT) to investigate the complexation between spherands containing five anisyl groups, with CH2–O–CH2 (2) and CH2–S–CH2 (3) units in an 18-membered macrocyclic ring, and the cationic guests (Li+, Na+, and K+). Our geometric structure results for spherands 1, 2, and 3 are in good agreement with the previously reported X-ray diffraction data. The absolute values of the binding energy of all the spherands are inversely proportional to the ionic radius of the guests. The results, taken as a whole, show that replacement of one anisyl group by CH2–O–CH2 (2) and CH2–S–CH2 (3) makes the cavity bigger and less preorganized. In addition, both the binding and specificity decrease for small ions. The spherands 2 and 3 appear beautifully preorganized to bind all guests, so it is not surprising that their binding energies are close to the parent spherand 1. Interestingly, there is a clear linear relation between the radius of the cavity and the binding energy (R2 = 0.999).Key words: spherands, preorganization, density functional theory, binding energy, cavity size.

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Physical genetics: Cross-breeding density functional theory and X-ray photoelectron spectroscopy to rationalize chemical shifts of binding energies in solid compounds

Solid State Sciences ◽

10.1016/j.solidstatesciences.2020.106359 ◽

2020 ◽

Vol 110 ◽

pp. 106359

Author(s):

Horst P. Beck ◽

Giuliano Moretti

Keyword(s):

Density Functional Theory ◽

Photoelectron Spectroscopy ◽

Density Functional ◽

Chemical Shifts ◽

Binding Energies ◽

Breeding Density ◽

Functional Theory ◽

X Ray ◽

Cross Breeding ◽

Solid Compounds

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STRUCTURES, ELECTRONIC AND MAGNETIC PROPERTIES OF C20 FULLERENES DOPED TRANSITION METAL ATOMS M@C20 (M = Fe, Co, Ti, V)

International Journal of Modern Physics C ◽

10.1142/s0129183110015968 ◽

2010 ◽

Vol 21 (12) ◽

pp. 1469-1477 ◽

Cited By ~ 5

Author(s):

M. SAMAH ◽

B. BOUGHIDEN

Keyword(s):

Density Functional Theory ◽

Magnetic Moment ◽

Density Functional ◽

Binding Energies ◽

Functional Theory ◽

Magnetic Dipoles ◽

Metal Atoms ◽

Transition Metal Atoms ◽

Semiconductor Behavior ◽

Co Doped

Structures, binding energies, magnetic and electronic properties endohedrally doped C 20 fullerenes by metallic atoms ( Fe , Co , Ti and V ) have been obtained by pseudopotential density functional theory. All M @ C 20, except Co @ C 20, are more stable than the undoped C 20 cage. The magnetic moment values are 1 and 2μB. These values and semiconductor behavior give to these compounds interesting feature in several technological applications. Titanium doped C 20 has a same magnetic moment than the isolated Ti atom. Hybridization process in the Co doped C 20 fullerene is most strong than in other doped cages. Electrical and magnetic dipoles calculated in the iron doped C 20 are very strong compared with other clusters.

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Research Optical Characteristics of H2S Molecule Adsorption on Agn (n=2,4,6) Clusters

Applied Mechanics and Materials ◽

10.4028/www.scientific.net/amm.321-324.499 ◽

2013 ◽

Vol 321-324 ◽

pp. 499-502

Author(s):

Hong Zhou ◽

Jun Feng Wang ◽

Jun Qing Wen ◽

Wei Bin Cheng ◽

Jun Fei Wang

Keyword(s):

Density Functional Theory ◽

Infrared Spectrum ◽

Density Functional ◽

Global Minimum ◽

Electronic States ◽

Binding Energies ◽

Optical Characteristics ◽

Functional Theory ◽

Calculation Results ◽

Planar Geometries

Density-functional theory has been used to calculate the energetically global-minimum geometries and electronic states of AgnH2S (n=2, 4, 6) clusters. The lowest-energy structures of Ag2, Ag4, Ag6, Ag2H2S, Ag4H2S and Ag6H2S clusters were obtained, respectively. The calculation results show that the lowest-energy structures of Ag2, Ag4and Ag6clusters are planar geometries. The binding energies of Agn(n=2, 4, 6) clusters are gradually increasing in our calculations. Compare the infrared spectrum peaks of Ag4cluster with that of Ag6cluster, which show that the peaks shift to shortwave. After adsorption, we found that the peaks shift to shortwave by comparison.

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Covalent Functionalization of Nickel Phosphide Nanocrystals with Aryl-Diazonium Salts

10.33774/chemrxiv-2021-3p4pp-v2 ◽

2021 ◽

Author(s):

Ian Murphy ◽

Peter Rice ◽

Madison Monahan ◽

Leo Zasada ◽

Elisa Miller ◽

...

Keyword(s):

Density Functional Theory ◽

Photoelectron Spectroscopy ◽

Density Functional ◽

Binding Energies ◽

Diazonium Salts ◽

Surface Functional Group ◽

Covalent Functionalization ◽

Substitution Pattern ◽

Core Electron ◽

Functional Theory

Covalent functionalization of Ni2P nanocrystals was demonstrated using aryl-diazonium salts. Spontaneous adsorption of aryl functional groups was observed, with surface coverages ranging from 20-96% depending on the native reactivity of the salt as determined by the aryl substitution pattern. Increased coverage was possible for low reactivity species using a sacrificial reductant. Functionalization was confirmed using thermogravimetric analysis, FTIR and X-ray photoelectron spectroscopy. The structure and energetics of this nanocrystal electrocatalyst system, as a function of ligand coverage, was explored with density functional theory calculations. The Hammett parameter of the surface functional group was found to linearly correlate with the change in Ni and P core-electron binding energies and the nanocrystal’s experimentally and computationally determined work-function. The electrocatalytic activity and stability of the functionalized nanocrystals for hydrogen evolution were also improved when compared to the unfunctionalized material, but a simple trend based on electrostatics was not evident. We used density functional theory to understand this discrepancy and found that H adsorption energies on the covalently functionalized Ni2P also do not follow the electrostatic trend and are predictive descriptors of the experimental results.

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Computation of bond dissociation energy for sulfides and disulfides with ab initio and density functional theory methods

International Journal of Quantum Chemistry ◽

10.1002/(sici)1097-461x(1997)62:3<291::aid-qua7>3.0.co;2-r ◽

1997 ◽

Vol 62 (3) ◽

pp. 291-296 ◽

Cited By ~ 62

Author(s):

Branko S. Jursic

Keyword(s):

Density Functional Theory ◽

Ab Initio ◽

Bond Dissociation Energy ◽

Dissociation Energy ◽

Density Functional ◽

Functional Theory ◽

Bond Dissociation

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Including dispersion interactions in the ONETEP program for linear-scaling density functional theory calculations

Proceedings of The Royal Society A Mathematical Physical and Engineering Sciences ◽

10.1098/rspa.2008.0398 ◽

2008 ◽

Vol 465 (2103) ◽

pp. 669-683 ◽

Cited By ~ 33

Author(s):

Quintin Hill ◽

Chris-Kriton Skylaris

Keyword(s):

Density Functional Theory ◽

Density Functional ◽

Computational Cost ◽

Density Functional Theory Calculations ◽

Binding Energies ◽

Molecular Structures ◽

Dispersion Interactions ◽

Biomolecular Systems ◽

Functional Theory ◽

High Level

While density functional theory (DFT) allows accurate quantum mechanical simulations from first principles in molecules and solids, commonly used exchange-correlation density functionals provide a very incomplete description of dispersion interactions. One way to include such interactions is to augment the DFT energy expression by damped London energy expressions. Several variants of this have been developed for this task, which we discuss and compare in this paper. We have implemented these schemes in the ONETEP program, which is capable of DFT calculations with computational cost that increases linearly with the number of atoms. We have optimized all the parameters involved in our implementation of the dispersion correction, with the aim of simulating biomolecular systems. Our tests show that in cases where dispersion interactions are important this approach produces binding energies and molecular structures of a quality comparable with high-level wavefunction-based approaches.

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