Electron Density Investigation of a Push–Pull Ethylene (C14H24N2O2⋅H2O) by X‐ray Diffraction atT= 21 K

Forni, Alessandra; Destro, Riccardo

doi:10.1002/chem.200305043

Cited by 35 publications

(19 citation statements)

References 70 publications

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“…The former option can be effected by steric congestion, as in the symmetrical compound C 1 (twist angle = 668; d C=C = 1.39 ), [11] whereas the latter is a result of p-bond polarization, as in C 2 (twist angle = 868; d C=C = 1.47 ). [12] The steric approach cannot be extended to allenes because the termini are too remote for significant interactions. Therefore, the only possible way to weaken the p bonds of allenes is by polarization, which can be accomplished by either a push-pull or a push-push substitution pattern.…”

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confidence: 99%

Synthesis of an Extremely Bent Acyclic Allene (A “Carbodicarbene”): A Strong Donor Ligand

et al. 2008

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Pushed to the limit: Pushing CC π bonds to the breaking point by using a push–push substitution pattern forces allenes to bend (see structure; C light blue, N dark blue). An acyclic allene featuring a CCC bond angle of 134.8° has been isolated in which the typically sp‐hybridized central carbon atom approaches a configuration that has two lone pairs of electrons, and acts as a very strong η1‐donor ligand for transition metals.

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confidence: 99%

Synthesis of an Extremely Bent Acyclic Allene (A “Carbodicarbene”): A Strong Donor Ligand

et al. 2008

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“…Specifically, with turning the acceptor part of the molecule out of the π-symmetry plane, the donor part of the molecule becomes increasingly nonplanar as well. In fact, each heteroatom, having approximately the planar sp 2 configuration in the S 0 minimum, becomes more pyramidal, i.e., closer to sp 3 , in the CdC twisted configurations; see Figures 1,2,4,and 5, and the Supporting Information. The mentioned large-amplitude motions are significantly more pronounced for molecules without internal constraints, such as 4-6.…”

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confidence: 96%

Correlated MO Study of the Low-Barrier Intramolecular Motions in Donor−Acceptor Ethenes

et al. 2005

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Correlated MP2 and MCSCF MO calculations of several model push-pull ethenes in most cases indicate no great participation of excited singlet and triplet electronic configurations in either the minima or the transition structures for the suggested facilitated intramolecular rotation about the polarized C=C bond. This situation changes significantly only in molecules with sulfur atoms in the molecule as either donors or acceptors. The outstanding contribution of sulfur atoms as either donors or acceptors is a significant increase of push-pull ethene molecular polarizabilities. Thus, within the studied small series of mostly planar push-pull ethenes, polarizability appears a better indicator of rapid intramolecular motions about the C=C bond than straight polarity. Substituents with larger steric demands around the C=C bond are shown to likely preclude its complete turnaround, thus prompting a ramification of the interpretations of dynamic NMR phenomena in sterically constrained push-pull ethenes as large-amplitude librations resulting from strong rovibrational and relatively weak electronic coupling. These librations, as shown by complete vibrational mode analysis of corresponding rotational transition structures, cover in fact certain sectors of the intuitively suggested full rotations similar to those about C-C single bonds.

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“…Because of more polar character, the transition state requires a greater degree of ordering of solvent molecules than the ground state, 9 leading to the negative entropy of activation. Rotational barriers in alkyl-substituted ethylenes are >55 kcal mol -1 , 10 while those of pushpull olefins, whose π-bonds are dramatically polarized, 11 are significantly lowered and shown in Table 2. 4a Rotational barrier (∆G ‡ = 24.4 kcal mol -1 ) of the isomerization of Z-2 to E-2 is much lower than those of the alkyl-substituted ethylenes, indicating that Z-2 is a push-pull olefin.…”

Section: Resultsmentioning

confidence: 99%

Ethyl (2-cyano-3-ethoxyacryloyl)carbamate: irreversibly thermal isomerization of a push-pull olefin

Sung¹,

Lin²,

Huang³

et al. 2005

Arkivoc

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A push-pull olefin, E-2, was prepared highly stereoselectively by reaction of ethyl (2-cyanoacetyl)carbamate, 1, with ethyl orthoformate in the presence of acetic anhydride. Forty percent of E-2 was isomerized to Z-2 after two hours of irradiation at 254 nm. All the Z-2 was isomerized back to E-2 spontaneously and irreversibly with Ea = 19.6 kcal mol -1 , ∆H ‡ = 19.0 kcal mol -1 , ∆S ‡ = -17.5 cal K -1 mol -1 , and ∆G ‡ = 24.4 kcal mol -1 . The negative entropy of activation for this isomerization indicates that the transition state has much more charge separation than the ground state. The low rotational barrier of this isomerization and very big chemical shift difference (∆δ C=C = 85.83 ppm) of two sp 2 -hybridized carbons of C=C partial double bond confirm 2 is a push-pull olefin.

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Electron Density Investigation of a Push–Pull Ethylene (C₁₄H₂₄N₂O₂⋅H₂O) by X‐ray Diffraction atT= 21 K

Cited by 35 publications

References 70 publications

Synthesis of an Extremely Bent Acyclic Allene (A “Carbodicarbene”): A Strong Donor Ligand

Synthesis of an Extremely Bent Acyclic Allene (A “Carbodicarbene”): A Strong Donor Ligand

Correlated MO Study of the Low-Barrier Intramolecular Motions in Donor−Acceptor Ethenes

Ethyl (2-cyano-3-ethoxyacryloyl)carbamate: irreversibly thermal isomerization of a push-pull olefin

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