Unified theory of resonance energies, ring currents, and aromatic character in the (4n + 2).pi.-electron annulenes

Haddon, Robert C.

doi:10.1021/ja00501a013

Cited by 150 publications

(77 citation statements)

References 19 publications

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“…[6] In this model, as formulated by McWeeny, [23] the ring current per unit area of a cycle is proportional to the reduced bond current, J rs , where p rs is the p bond-order between adjacent atoms r and s and p rs,rs is the imaginary bond-bond polarisability. [1] J rs ¼ ðp rs þbp rs,rs Þb…”

Section: Currents In Carbocyclesmentioning

confidence: 99%

“…Hückel s long-standing 4n+2 rule distinguishes aromatic from antiaromatic monocycles, and correlates the energetics of these systems with their characteristic magnetic properties. [1] However, the periodic table offers wide possibilities for the construction of isoelectronic heterocycles, and for many of them, direct transferability of the implied relationship between aromaticity and electron count is questionable or even counterfactual. The replacement of CC by BN, for example, is known to lead to marked differences in magnetic properties: [2] the strong ring currents of the carbocycle vanish in the isoelectronic azabora-heterocycles, B N/2 N N/2 H N (1-3).…”

Section: Introductionmentioning

confidence: 99%

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A Unified Orbital Model of Delocalised and Localised Currents in Monocycles, from Annulenes to Azabora‐heterocycles

Soncini

Domene

Engelberts

et al. 2005

Chemistry A European J

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Why are some (4n+2)π systems aromatic, and some not? The ipsocentric approach to the calculation of the current density induced in a molecule by an external magnetic field predicts a four‐electron diatropic (aromatic) ring current for (4n+2)π carbocycles and a two‐electron paratropic (antiaromatic) current for (4n)π carbocycles. With the inclusion of an electronegativity parameter, an ipsocentric frontier‐orbital model also predicts the transition from delocalised currents in carbocycles to nitrogen‐localised currents in alternating azabora‐heterocycles, which rationalises the differences in (magnetic) aromaticity between these isoelectronic π‐conjugated systems. Ab initio valence‐bond calculations confirm the localisation predicted by the naïve model, and coupled‐Hartree–Fock calculations give current‐density maps that exhibit the predicted delocalised‐to‐localised/carbocycle–heterocycle transition.

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Section: Currents In Carbocyclesmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

A Unified Orbital Model of Delocalised and Localised Currents in Monocycles, from Annulenes to Azabora‐heterocycles

Soncini

Domene

Engelberts

et al. 2005

Chemistry A European J

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“…Neither Haddon nor we could derive any analytical relationship between the intensity of the ring current and the ASE for antiaromatic annulenes. 83,86 In marked contrast to MRE, TRE and DRE 30,35 always take finite values even for antiaromatic annulenes. Bond-equalized antiaromatic annulenes, however, are not likely to have real existence since they are very unstable with respect to distortion.…”

Section: Magnetic Resonance Energies Of Antiaromatic Speciesmentioning

confidence: 95%

“…82 Haddon found in 1979 that the intensity of a ring current induced in an aromatic annulene is proportional not only to the ring area but also to the ASE. 83 He employed as an ASE one formerly used by us called A-I resonance energy, 26,84 which we later ceased to use because it can be applied only to monocyclic π-systems. This kind of ASE (ASE A-I ) was evaluated by reference to the unit bond energy of infinite annulene.…”

Section: The Origin Of Ring-current Diamagnetismmentioning

confidence: 99%

“…Equations 80 and 81 tell us that the circuit-current susceptibility is proportional not only to the area enclosed by the circuit squared but also to CRE, whereas the intensity of the circuit current is proportional not only to the circuit area but also to CRE. We can now safely say that, as in the case of monocyclic aromatic annulenes, 83,86 the intensity of every circuit current and the circuit-current susceptibility for polycyclic π-systems run parallel with the ASE arising from the circuit. This fact supports the commonly accepted view that, for some reason or other, ring-current diamagnetism reflects the aromaticity of the π-system.…”

Section: 45mentioning

confidence: 99%

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Graph Theory of Ring-Current Diamagnetism

Aihara

2017

Bulletin of the Chemical Society of Japan

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Various magnetic criteria of aromaticity have been proposed so far, because they are easily calculated and applicable to a variety of cyclic π-systems. Many researchers, however, are reluctant to accept all or some of them. Our graph theory of ring-current diamagnetism revealed serious flaws in familiar magnetic criteria of aromaticity. Physically meaningful information on aromaticity can nevertheless be extracted from the ring-current diamagnetism. In particular, magnetic resonance energy (MRE), derived from the ring-current diamagnetic susceptibility, is interpretable as a kind of aromatic stabilization energy (ASE) and helps in consistently interpreting energetic and magnetic criteria of aromaticity. MRE and related quantities can be determined without reference to any hypothetical polyene-like structure but with a reasonable assumption that, when a magnetic field is applied to a cyclic π-system, a current is induced in each circuit in proportion to the ASE arising from the circuit. Unlike other conventional magnetic indexes, they are independent of the size and shape of the π-system.

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Ring currents in condensed ring systems

Anusooya

Chakrabarti

Pati

et al. 1998

Int. J. Quant. Chem.

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ABSTRACT:We have studied magnetism and aromaticity of polycyclic ring systems by analyzing ring currents for different circulations in these molecules. The technique employed for calculating ring currents uses correction vectors which implicitly includes all the eigenstates of the Hamiltonian in the space of the chosen configurations. We have employed the Pariser᎐Parr᎐Pople Hamiltonian and have carried out full configuration Ž . interaction CI calculations for small systems and approximate CI calculations for large systems. The systems studied include polyacenes, nonaromatic ring systems including the C fragments pyracylene, fluoranthene, and corannulene, and heteroatomic systems 60 with upto two six-membered rings. We find that in polyacenes, the aromaticity of the extreme phenyl rings reduces with increasing number of phenyl rings in the system, and 2 it saturates at f the benzene value. In systems containing nonaromatic rings, we find 3 paramagnetic or diamagnetic behavior for different circulations depending upon the number of atoms in the chosen ring cycle, in agreement with the 4 n q 2 rule. In corannulene, the largest fragment of C we have studied, the five-membered ring is 60 weakly diamagnetic while the six-membered ring is more diamagnetic, although much less than in isolated benzene. The ring structures with heteroatoms studied are pyridine, pyrimidine, and its isomers, s-triazine, quinoline and its isomer, and quinazoline and its isomers. All these have similar ring currents as in their purely carbon counterparts, although ions of these molecules show interesting behavior.

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Unified theory of resonance energies, ring currents, and aromatic character in the (4n + 2).pi.-electron annulenes

Cited by 150 publications

References 19 publications

A Unified Orbital Model of Delocalised and Localised Currents in Monocycles, from Annulenes to Azabora‐heterocycles

A Unified Orbital Model of Delocalised and Localised Currents in Monocycles, from Annulenes to Azabora‐heterocycles

Graph Theory of Ring-Current Diamagnetism

Ring currents in condensed ring systems

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