Chemical Bonding and σ-Aromaticity in Charged Molecular Alloys: [Pd2As14]4− and [Au2Sb14]4− Clusters

You, Xue Rui; Feng, Lin Yan; Li, Rui; Zhai, Hua Jin

doi:10.1038/s41598-017-00867-5

Cited by 7 publications

(8 citation statements)

References 57 publications

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“…The name of benzene is almost an equivalent to the concept of aromaticity; aromaticity of benzene has been investigated extensively both in its ground and excited states . Aromaticity is an elusive phenomenon that has been employed by chemists to explain exceptional stability or justify particular reactivity of various molecules . IUPAC recommends four criteria – structural, energetic, electronic, and magnetic (SEEM) – to characterize aromatic species .…”

Section: Introductionmentioning

confidence: 99%

Why is Benzene Unique? Screening Magnetic Properties of C₆H₆Isomers

Janda

Foroutan‐Nejad

2018

ChemPhysChem

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Magnetic properties are commonly used to identify new aromatic molecules because it is generally believed that magnetization and energetic stability are correlated. To verify the potential correlation between the energy and magnetic response properties, we examined a set of 198 isomers of C H . The energy and magnetic properties of these molecules can be directly compared with no need to invoke any arbitrary reference state because the studied systems are all isomers. Benzene is the global minimum on the potential energy surface of C H , 35 kcal mol lower in energy than the second most stable isomer, fulvene. Unlike its electronic energy, isotropic magnetizability of benzene is slightly lower than the average magnetizability of its isomers. Altogether, 44 isomers of C H were identified to have more negative magnetic susceptibility than benzene but were between 67.0 to 168.6 kcal mol higher in energy than benzene. However, benzene is unique in two ways. Analyzing the paramagnetic contribution to the magnetic susceptibility as originally suggested by Bilde and Hansen (Mol. Phys., 1997, 92, 237) revealed that 53 molecules have lower paramagnetic susceptibility than benzene but among monocyclic systems benzene has the least paramagnetic susceptibility. Furthermore, benzene has the largest out-of-plane magnetic susceptibility that originates from the strongest ring current among all studied species.

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Section: Introductionmentioning

confidence: 99%

Why is Benzene Unique? Screening Magnetic Properties of C₆H₆Isomers

Janda

Foroutan‐Nejad

2018

ChemPhysChem

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“…Thus, they indicate 3-fold delocalization in 4 , that is, 3-fold (π and σ) aromaticity. This bonding picture is depicted in Figure , which overrides the 18-electron rule. − Note that 10σ, 2π, and 6σ electron-counting all conform to the (4 n + 2) Hückel rule. − NICS calculations offer an independent probe for aromaticity. NICS(0) and NICS(1), calculated at the ring center and 1 Å above it, characterize σ and π aromaticity, respectively.…”

Section: Discussionmentioning

confidence: 98%

Star-Like CBe₅Au₅⁺ Cluster: Planar Pentacoordinate Carbon, Superalkali Cation, and Multifold (π and σ) Aromaticity

et al. 2018

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We report on the computational design of star-like CBeAu cluster with planar pentacoordinate carbon (ppC), which is also classified as a superalkali cation. Relevant isovalent CBeAu (n = 2-4), BBeAu, and NBeAu clusters with ppC/B/N are studied as well. Global-minimum structures of the clusters are established via computer global searches. The species feature a pentacoordinate pentagonal XBe (X = C, B, N) core, with Au occupying outer bridging positions. Molecular dynamics simulations indicate that they are dynamically stable. Bonding analysis reveals 3-fold (π and σ) aromaticity in CBeAu, a key concept that overrides the 18-electron rule and should be applicable for (or help revisit existing models of) other planar hypercoordinate systems. Vertical electron affinities of CBeAu and its lighter counterparts (CBeCu and CBeAg) are calculated to be unusually low, which are below 3.89 eV, the smallest atomic ionization potential of any element in the periodic table. Thus, these three clusters belong to superalkali cations. The merge of ppC and superalkali characters makes them unique chemical species.

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“…Many such species have been successfully described by the AdNDP (adaptive natural density partitioning) method of Zubarev and Boldyrev and its solid-state (SSAdNDP) generalization . Aside from the well-known 3c/2e hypovalent bonding in borane-type species, strong computational and experimental evidence has been found for higher-order multicenter bonding in a broad variety of metallic clusters and other species of unusual charge, spin multiplicity, and coordination pattern . The RNBO approach adheres somewhat more closely to the localized few-center strategy of general NBO/NRT description (rather than fully delocalized MO-like description for partitions that fail to yield well-localized NBOs) but can be expected to closely resemble or complement AdNDP description when both methods are applicable.…”

Section: Concluding Discussionmentioning

confidence: 99%

Resonance Natural Bond Orbitals: Efficient Semilocalized Orbitals for Computing and Visualizing Reactive Chemical Processes

Glendening

Weinhold

2019

J. Chem. Theory Comput.

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We describe a practical algorithm for calculating NBO-based “resonance natural bond orbitals” (RNBOs) that can accurately describe the localized bond shifts of a reactive chemical process. Unlike conventional NBOs, the RNBOs bear no fixed relationship to a particular Lewis-structural bonding pattern but derive instead from the natural resonance theory (NRT)-based manifold of all bonding patterns that contribute significantly to resonance mixing (and associated multichannel reactivity) at a chosen point of the potential energy surface. The RNBOs typically retain familiar localized Lewis-structural character for stable near-equilibrium species, yet they freely adopt multicenter character as required to satisfy Pople’s prerequisite that no allowed computational basis set should be inherently biased toward a particular nuclear arrangement or bonding pattern. A simple numerical application to intramolecular Claisen rearrangement demonstrates the computational and conceptual advantages of describing reactive bond-shifts with RNBOs rather than other conventional NBO- or MO-based expansion sets.

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Chemical Bonding and σ-Aromaticity in Charged Molecular Alloys: [Pd2As14]4− and [Au2Sb14]4− Clusters

Cited by 7 publications

References 57 publications

Why is Benzene Unique? Screening Magnetic Properties of C₆H₆Isomers

Why is Benzene Unique? Screening Magnetic Properties of C₆H₆Isomers

Star-Like CBe₅Au₅⁺ Cluster: Planar Pentacoordinate Carbon, Superalkali Cation, and Multifold (π and σ) Aromaticity

Resonance Natural Bond Orbitals: Efficient Semilocalized Orbitals for Computing and Visualizing Reactive Chemical Processes

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Chemical Bonding and σ-Aromaticity in Charged Molecular Alloys: [Pd2As14]4− and [Au2Sb14]4− Clusters

Cited by 7 publications

References 57 publications

Why is Benzene Unique? Screening Magnetic Properties of C6H6Isomers

Why is Benzene Unique? Screening Magnetic Properties of C6H6Isomers

Star-Like CBe5Au5+ Cluster: Planar Pentacoordinate Carbon, Superalkali Cation, and Multifold (π and σ) Aromaticity

Resonance Natural Bond Orbitals: Efficient Semilocalized Orbitals for Computing and Visualizing Reactive Chemical Processes

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Why is Benzene Unique? Screening Magnetic Properties of C₆H₆Isomers

Why is Benzene Unique? Screening Magnetic Properties of C₆H₆Isomers

Star-Like CBe₅Au₅⁺ Cluster: Planar Pentacoordinate Carbon, Superalkali Cation, and Multifold (π and σ) Aromaticity