The Nature of the Chemical Bond Revisited: An Energy‐Partitioning Analysis of Nonpolar Bonds

Kovács, Attila; Esterhuysen, Catharine; Frenking, Gernot

doi:10.1002/chem.200400525

Cited by 138 publications

(73 citation statements)

References 80 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…93 EDA has been proven to be a reliable and a powerful tool, improving our understanding of the nature of chemical bonding not only in the main group, 94,95 but also in transitionmetal compounds. 96,97 Since this method is discussed in detail in the current literature, 84,90 we will describe the theory involved only briefly.…”

Section: Methodsmentioning

confidence: 99%

The nature of Ru–NO bonds in ruthenium tetraazamacrocycle nitrosyl complexes—a computational study

et al. 2012

Self Cite

View full text Add to dashboard Cite

2012The nature of Ru-NO bonds in ruthenium tetraazamacrocycle nitrosyl complexes-a computational study DALTON TRANSACTIONS, CAMBRIDGE, v. 41, n. 24, Ruthenium complexes including nitrosyl or nitrite complexes are particularly interesting because they can not only scavenge but also release nitric oxide in a controlled manner, regulating the NO-level in vivo.The judicious choice of ligands attached to the [RuNO] core has been shown to be a suitable strategy to modulate NO reactivity in these complexes. In order to understand the influence of different equatorial ligands on the electronic structure of the Ru-NO chemical bonding, and thus on the reactivity of the coordinated NO, we propose an investigation of the nature of the Ru-NO chemical bond by means of energy decomposition analysis (EDA), considering tetraamine and tetraazamacrocycles as equatorial ligands, prior to and after the reduction of the {RuNO} 6 moiety by one electron. This investigation provides a deep insight into the Ru-NO bonding situation, which is fundamental in designing new ruthenium nitrosyl complexes with potential biological applications.

show abstract

Section: Methodsmentioning

confidence: 99%

The nature of Ru–NO bonds in ruthenium tetraazamacrocycle nitrosyl complexes—a computational study

et al. 2012

Self Cite

View full text Add to dashboard Cite

show abstract

“…[11][12][13][14]. EDA can provide useful information on the p conjugation and the nature of the bonds 15 or even explain the way the position of the substituents can influence a reaction site through resonance and field/inductive effects. 16 EDA calculations have been performed at the BP86/ TZ2P level of theory [17][18][19] and the ADF code 12,20,21 fragmenting the system into three parts: the benzene ring, the aldehyde and the nitro group.…”

Section: Computational Detailsmentioning

confidence: 99%

A comparative analysis of the UV/Vis absorption spectra of nitrobenzaldehydes

Leyva

Corral

Schmierer

et al. 2011

Phys. Chem. Chem. Phys.

View full text Add to dashboard Cite

In a joint experimental and theoretical study, the UV/Vis absorption spectra of the three isomers (ortho, meta, para) of nitrobenzaldehyde (NBA) were analyzed. Absorption spectra are reported for NBA vapors, cyclohexane and acetonitrile solutions. All spectra are poor in vibronic structure and hardly affected in shape by the surroundings (vapor or solution). Moderate solvatochromic shifts of BÀ0.2 eV are measured. For all isomers vertical transition energies, oscillator strengths, and excited state dipole moments were computed using the MS-CASPT2/CASSCF and CC2 methods. Based on these calculations the experimental transitions were assigned. The spectra of all isomers are characterized by weak (e max E 100 M À1 cm À1) transitions around 350 nm (3.6 eV), arising from np* absorptions starting from the lone pairs of the nitro and aldehyde moieties. The next band of intermediate intensity peaking around 300 nm (4.2 eV, e max E 1000 M À1 cm À1) is dominated by pp* excitations within the arene function. Finally, strong absorptions (e max E 10 000 M À1 cm À1 ) were observed around 250 nm (5.0 eV) which we ascribe to pp* excitations involving the nitro and benzene groups.

show abstract

“…Here we will not discuss the different components in detail, since this has already been done in previous publications 39,40 focusing instead on the comparison between the Mayer and the EDA scheme at the DFT level. …”

Section: Ziegler-rauk Energy Decomposition Resultsmentioning

confidence: 99%

“…A recent EDA study 39,40 on the nature of the chemical bond in a number of nonpolar, strongly bound molecules such as N 2 highlighted the importance of the electrostatic contribution ⌬E elstat even in such systems that are traditionally discussed solely on the basis of covalent contributions. In N 2 this electrostatic contribution amounts to −311.2 kcal mol −1 , which corresponds to one-third of the overall stabilizing contributions ͑⌬E elstat + ⌬E orb ͒ to the interaction energy.…”

Section: Comparisonmentioning

confidence: 99%

Two complementary molecular energy decomposition schemes: The Mayer and Ziegler–Rauk methods in comparison

Vyboishchikov

Krapp²,

Frenking³

2008

The Journal of Chemical Physics

Self Cite

View full text Add to dashboard Cite

In the present paper we discuss and compare two different energy decomposition schemes: Mayer's Hartree-Fock energy decomposition into diatomic and monoatomic contributions ͓Chem. Phys. Lett. 382, 265 ͑2003͔͒, and the Ziegler-Rauk dissociation energy decomposition ͓Inorg. Chem. 18, 1558 ͑1979͔͒. The Ziegler-Rauk scheme is based on a separation of a molecule into fragments, while Mayer's scheme can be used in the cases where a fragmentation of the system in clearly separable parts is not possible. In the Mayer scheme, the density of a free atom is deformed to give the one-atom Mulliken density that subsequently interacts to give rise to the diatomic interaction energy. We give a detailed analysis of the diatomic energy contributions in the Mayer scheme and a close look onto the one-atom Mulliken densities. The Mulliken density A has a single large maximum around the nuclear position of the atom A, but exhibits slightly negative values in the vicinity of neighboring atoms. The main connecting point between both analysis schemes is the electrostatic energy. Both decomposition schemes utilize the same electrostatic energy expression, but differ in how fragment densities are defined. In the Mayer scheme, the electrostatic component originates from the interaction of the Mulliken densities, while in the Ziegler-Rauk scheme, the undisturbed fragment densities interact. The values of the electrostatic energy resulting from the two schemes differ significantly but typically have the same order of magnitude. Both methods are useful and complementary since Mayer's decomposition focuses on the energy of the finally formed molecule, whereas the Ziegler-Rauk scheme describes the bond formation starting from undeformed fragment densities.

show abstract

The Nature of the Chemical Bond Revisited: An Energy‐Partitioning Analysis of Nonpolar Bonds

Cited by 138 publications

References 80 publications

The nature of Ru–NO bonds in ruthenium tetraazamacrocycle nitrosyl complexes—a computational study

The nature of Ru–NO bonds in ruthenium tetraazamacrocycle nitrosyl complexes—a computational study

A comparative analysis of the UV/Vis absorption spectra of nitrobenzaldehydes

Two complementary molecular energy decomposition schemes: The Mayer and Ziegler–Rauk methods in comparison

Contact Info

Product

Resources

About