Vibrational spectrum, structure, and energy of [1.1.1]propellane

Wiberg, Kenneth B.; Dailey, William P.; Walker, Frederick H.; Waddell, Sherman T.; Crocker, Louis S.; Newton, Marshall D.

doi:10.1021/ja00311a003

Cited by 123 publications

(95 citation statements)

References 3 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…1 On the other hand, many arguments derived mainly from spectral studies, including those of classical vibrational spectroscopy, 24,25 low-energy electron impact spectroscopy, 26 photoelectron spectroscopy 27 and electron momentum spectroscopy, 28,29 lead to the conclusion that the bridgehead-bridgehead bond in propellane should be interpreted as an ordinary chemical bond, but with inverted bonding hybrids. In the last study, 29 the complete valence electronic structure of propellane was reported and the resulting wavefunction was determined, which enabled the authors to derive a number of its molecular properties, confirming, in particular, the physical existence of the central bridgehead-bridgehead bond with a 0.70 bond order (very similar to that of 0.73 derived by Wiberg et al 10 ). The strength of this 'bond phantom' was estimated to be ca 60 kcal mol 1 , 30 whereas according to NBO analysis 31 the occupancy of the central bonding orbital is 1.83 and that of the antibonding orbital is 0.15.…”

Section: Introductionmentioning

confidence: 52%

“…8 In spite of its remarkable deviation from tetrahedral geometry characterized by inverted carbons at bridgeheads and considerable steric strain of 98 kcal mol 1 (1 kcal D 4.184 kJ), 9 propellane was found to be surprisingly stable. 10 The relatively high chemical stability of propellane was explained 7 by the fact that breaking of the central bridgehead-bridgehead bond releases only less than one-third of its strain energy while breaking of the peripheral carbon-carbon bond is symmetryforbidden. Higher propellanes with enlarged fused rings have also received a good deal of attention and it was a challenging task to apply the second-order polarization propagator approach (SOPPA) 11 to calculate carbon-carbon spin-spin coupling constants, J(C,C), in the series of propellanes 1-6 in continuation of our previous communications dealing with the three-membered rings, symmetries are given in Table 1.…”

Section: Introductionmentioning

confidence: 99%

“…[1.1.1]Propellane (1) As follows from the pioneering non-empirical calculations by Newton and Schulman 20 (performed long before the propellane itself had been synthesized), and from more recent studies by Wiberg and co-workers 10,21 and many others, 22,23 the bridgehead-bridgehead bond of propellane shows an essentially antibonding nature because the bonding electron density and electrostatic potential are 'inverted', i.e. directed out of the molecule along the C 1 -C 3 axis.…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Non‐empirical calculations of NMR indirect carbon–carbon coupling constants. Part 6: Propellanes

Krivdin

2003

Magnetic Reson in Chemistry

View full text Add to dashboard Cite

A full set of carbon-carbon coupling constants have been calculated at the SOPPA level in the series of six most representative propellanes. Special attention was focused on spin-spin couplings involving both bridgehead carbons, and these data were rationalized in terms of the multipath coupling mechanism and hybridization effects. Many unknown couplings in the propellane frameworks were predicted with high reliability.

show abstract

Section: Introductionmentioning

confidence: 52%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Non‐empirical calculations of NMR indirect carbon–carbon coupling constants. Part 6: Propellanes

Krivdin

2003

Magnetic Reson in Chemistry

View full text Add to dashboard Cite

show abstract

“…Although of a relatively short distance, the fusion bond in the cyclopropane rings is subject to considerable variation as observed in the X-ray crystal structure of 11 (Sect. 2.2) and could possibly be considered a weaker than normal C-C bond, as had been discussed for [I .I .l]propellane [42]. Actually, the effective bridgehead or fusion C-C single-bond strength in both [l.l.l]propellane as well as in 6-6-closed methanofullerenes seems not to be established.…”

Section: The Different Effects On Physical Properties and Chemical Rementioning

confidence: 96%

Bis‐ through Tetrakis‐Adducts of C₆₀ by Reversible Tether‐Directed Remote Functionalization and systematic investigation of the changes in fullerene properties as a function of degree, pattern, and nature of functionalization

Cardullo¹,

Seiler²,

Isaacs³

et al. 1997

Helvetica Chimica Acta

110

View full text Add to dashboard Cite

By the tether-directed remote functionalization method, a series of bis-to hexakis-adducts of C,,, i.e., 1-7 (Fig. I ) , had previously been prepared with high regioselectivity. An efficient method for the removal of the tether-reactive-group conjugate was now developed and its utility demonstrated in the regioselective synthesis of bis-to tetrakis(methano)fullerenes (= di-to tetracyclopropafullerenes-C,,-Z,,) 9-11 starting from 4, 5, and 7, respectively (Schemes 2 , 4 , and 5). This versatile protocol consists of a '0, ene reaction with the two cyclohexene rings in the starting materials, reduction of the formed mixture of isomeric allylic hydroperoxides to the corresponding alcohols, acid-promoted elimination of H,O to cyclohexa-I ,3-dienes, Diels-Alder addition of dimethyl acetylenedicarboxylate, retro-Diels-Alder addition, and, ultimately, transesterification. In the series 9-11, all methano moieties are attached along an equatorial belt of the fullerene. Starting from C,,-symmetrical tetrakis-adduct 15, transesterification with dodecan-1-01 or octan-1-01 yielded the octaesters 16 and 17, respectively, as noncrystalline fullerene derivatives (Scheme 3). The X-ray crystal structure of a CHCI, solvate of 11 (Fig. 3) showed that the residual conjugated n-chromophore of the C-sphere is reduced to two tetrabenzopyracylene substructures connected by four biphenyl-type bonds (Fig. 5). In the eight six-membered rings surrounding the two pyracylene (= cyclopentlfg]acenaphthylene) moieties, 6-6 and 6-5 bond-length alteration (0.05 A) was reduced by ca. 0.01 8, as compared to the free C,, skeleton (0.06 A) (Fig. I). The crystal packing (Fig. 6 ) revealed short contacts between C1-atoms of the solvent molecule and sp2-and sp3-C-atoms of the C-sphere, as well as short contacts between C1-atoms and 0-atoms of the EtOOC groups attached to the methano moieties of 11. The physical properties and chemical reactivity of compounds 1 -11 were comprehensively investigated as a function of degree and pattern of addition and the nature of the addends. Methods applied to this study were UV/VIS (Figs. 7 -I f ) , IR, and NMR spectroscopy (Table 2), cyclic (CV) and steady-state (SSV) voltammetry (Table I ) , calculations of the energies of the lowest unoccupied molecular orbitals (LUMOs) and electron affinities (Figs. I2 and f3), and evaluation of chemical reactivity in competition experiments. It was found that the properties of the fullerene derivatives were not only affected by the degree and pattern of addition but also, in a remarkable way, by the nature of the addends (methano vs. but-2-ene-1,4-diyl) anellated to the C-sphere. Attachment of multiple methano moieties along an equatorial belt as in the series 8-11 induces only a small perturbation of the original fullerene n-chromophore. In general, with increasing attenuation of the conjugated fullerene n-chromophore, the optical (HOMO-LUMO) gap in the UVjVIS spectrum is shifted to higher energy, the number of reversible one-electron reductions decreases, and the first reduction p...

show abstract

“…Surprisingly, there are almost no thermochemical data for any propellane except for reaction calorimetry for the simplest one, the triple cyclopropane [1.1.1] species [90], and the likewise cyclopropane-containing [3.2.1] species [91]. Even more surprisingly, calorimetric data for species with two or more cyclic ester groups (i.e.…”

Section: Introductionmentioning

confidence: 99%

Interplay of Thermochemistry and Structural Chemistry, the Journal (Volume 13, 2002) and the Discipline

Stem¹,

Liebman

2005

Struct Chem

View full text Add to dashboard Cite

Vibrational spectrum, structure, and energy of [1.1.1]propellane

Cited by 123 publications

References 3 publications

Non‐empirical calculations of NMR indirect carbon–carbon coupling constants. Part 6: Propellanes

Non‐empirical calculations of NMR indirect carbon–carbon coupling constants. Part 6: Propellanes

Bis‐ through Tetrakis‐Adducts of C₆₀ by Reversible Tether‐Directed Remote Functionalization and systematic investigation of the changes in fullerene properties as a function of degree, pattern, and nature of functionalization

Interplay of Thermochemistry and Structural Chemistry, the Journal (Volume 13, 2002) and the Discipline

Contact Info

Product

Resources

About

Vibrational spectrum, structure, and energy of [1.1.1]propellane

Cited by 123 publications

References 3 publications

Non‐empirical calculations of NMR indirect carbon–carbon coupling constants. Part 6: Propellanes

Non‐empirical calculations of NMR indirect carbon–carbon coupling constants. Part 6: Propellanes

Bis‐ through Tetrakis‐Adducts of C60 by Reversible Tether‐Directed Remote Functionalization and systematic investigation of the changes in fullerene properties as a function of degree, pattern, and nature of functionalization

Interplay of Thermochemistry and Structural Chemistry, the Journal (Volume 13, 2002) and the Discipline

Contact Info

Product

Resources

About

Bis‐ through Tetrakis‐Adducts of C₆₀ by Reversible Tether‐Directed Remote Functionalization and systematic investigation of the changes in fullerene properties as a function of degree, pattern, and nature of functionalization