Time-dependent density functional theory treatment of the first UV absorption band in all-transoid permethyloligosilanes SinMe2n+2 (n = 2-8, 10)

Rooklin, David; Schepers, Thorsten; Raymond-Johansson, Mary K.; Michl, Josef

doi:10.1039/b302087h

Cited by 22 publications

(48 citation statements)

References 65 publications

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“…It also provides additional confirmation of the presence of at least three transitions in the constrained tetrasilanes 2-4 and allows the detection of a weak lowest-energy transition in 5 and 6 that had been postulated (28,31) to play a crucial role in the thermochromism of short-chain oligosilanes. The spectrum of the open chain, n-Si 4 Me 10 (6), is in agreement with the dominance of the transoid conformer in its room-temperature solution.…”

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confidence: 81%

“…Less reliable time-dependent (TD) density functional theory (DFT) calculations, available at the Becke three-parameter hybrid functional combined with Lee-YangParr correlation functional (B3LYP)͞double zeta (DZ) level for a large number of dihedral angles, produced similar results for the lowest six states of n-Si 4 Me 10 (6). B3LYP͞DZ and B3LYP͞ triple zeta results are also available for certain conformations of permethylated chains up to n-Si 10 Me 22 (28). Results of even more approximate calculations on peralkylated oligosilanes were published earlier (10,25,29).…”

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confidence: 94%

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Magnetic circular dichroism of peralkylated tetrasilane conformers

Fogarty

Imhof

Michl

2004

Proc. Natl. Acad. Sci. U.S.A.

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Magnetic circular dichroism (MCD) of five peralkylated tetrasilanes (1-5) conformationally constrained to angles ranging from nearly 0°to 180°and of the open chain tetrasilane Si4Me10 (6) shows a clear conformational dependence and permits the detection of previously hidden transitions. In the tetrasilane CH2Si4Me8 (1), with the smallest dihedral angle, comparison of MCD with absorption spectra reveals four low-energy electronic transitions. In the tetrasilanes 2-4, three distinct transitions are apparent. In tetrasilanes 5 and 6, MCD reveals the very weak transition that has been predicted to be buried under the first intense peak and to which the anomalous thermochromism of 6 and other short-chain oligosilanes has been attributed. Linear oligosilanes and polysilanes, Si n R 2nϩ2 (R ϭ alkyl), are fully saturated hydrocarbon analogs with very unusual optical properties and have been of potential practical interest, for instance, as nonlinear optical materials, photoresists, and charge conductors (1, 2).They are of considerable theoretical interest as well. Their most striking property is long-wavelength absorption and luminescence. For long peralkylated polysilane chains, the first absorption peak is in the near-UV range, between 330 and 380 nm (3), and the emission peak is at somewhat longer wavelengths (4). Emission from shorter oligosilane chains often peaks at the edge of the visible (5), and occasionally at wavelengths as long as 500 nm (6). The conformational behavior of these flexible chains is extraordinarily rich (7,8). Six potential energy minima are generally available for torsion about each internal Si-Si bond, many conformers tend to have comparable energies, and barriers to their interconversion are low. In permethylated oligosilanes, the calculated preferred absolute values of backbone dihedral angles are Ϸ55°(gauche), Ϸ90°(ortho), and Ϸ165°(transoid) (9 -12). In oligosilanes with longer alkyl substituents, other angles (deviant and cisoid) can occur as well (13,14).The electronic absorption and emission spectra of these compounds are very sensitive to chain conformation, as manifested in the thermochromism (15, 16), piezochromism (17), solvatochromism (18), and related properties (19, 20) of polysilanes. They therefore represent an especially suitable vehicle for the study of the incompletely understood but clearly important phenomenon of -electron delocalization and particularly of its structural and conformational dependence. This dependence is important for many properties such as charge and energy transfer and substituent effect and spin-density propagation across saturated systems. Detailed analysis and assignment of electronic transitions of oligosilanes as a function of conformation are therefore important, but they are difficult. The absorption bands are broad and closely spaced, making the detection of weakly allowed transitions difficult. Essentially nothing is known about the triplet states of these molecules; they do not contribute significantly to ordinary absorption spectra, and we ...

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mentioning

confidence: 81%

mentioning

confidence: 94%

Magnetic circular dichroism of peralkylated tetrasilane conformers

Fogarty

Imhof

Michl

2004

Proc. Natl. Acad. Sci. U.S.A.

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“…The only observedi ntensea bsorption maximum gradually shifts from 43 100 cm À1 in Si 4 Me 10 to 34 100 cm À1 in Si 10 Me 22 , and gains af actor of nearly 10 in intensity in the process. The long-axis polarized excitationst ot he first and only calculated strongly allowed excited state of B symmetry are in good agreement with the positions of the intense bands apparent in the observed absorption spectra.A ll calculated energies are slightly too high (perhaps owing to solvent effects).…”

Section: (Iii) S-delocalized and S-localized Conformersmentioning

confidence: 92%

“…None of the four lowest transitions have significant intensity.T his has ad ramatic effect on the appearance of the calculated absorption spectra, as is illustrated for Si 13 Me 28 in Figure 4( the peak half-widtha th alf maximum, 700 cm À1 ,w as chosen to fit roughlyt he shapeo ft he low-temperatures pectrum of all-[t]-1 [10]). [22] Down to 1508,t he transition to the 1B state is the strongest, but at 1208,i ta lready only appearsw eakly and 2B with 3B carry far more oscillator strength.T he trend continues, and the calculated absorption spectra of the all-o and all-g conformers do not show any intense absorption at lowenergies. The increase in the energy of the 1B transition, the gradual shift of oscillator strength to higher energy transitions, and the reduced separation between transitions as w decreases are striking.…”

Section: Regular Helical Oligosilanesmentioning

confidence: 97%

“…In peralkylated n-tetrasilanes, the spectra of which have been studied in considerable detail in as eries of conformations, these additional transitions have been uncovered and are in impressive agreement with the resultso fT D-DFT/TZ, CAS-PT2, and SAC-CI calculations. [4,22,25] Al ess detaileds tudy is availablefor af ew conformers of peralkylated hexasilanes. [49] The right-hand side of Figure 2s erves only for highlighting the contrast between s-delocalized and a s-localized behavior and will be dealt with in more detail elsewhere.…”

Section: (Iii) S-delocalized and S-localized Conformersmentioning

confidence: 99%

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Intuitive Understanding of σ Delocalization in Loose and σ Localization in Tight Helical Conformations of an Oligosilane Chain

Jovanović

Antic

Rooklin

et al. 2017

Chemistry An Asian Journal

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Conformational effects on the s-electron delocalization in oligosilanes are addressed by Hartree-Fock and time-dependent density functional theory calculations (B3LYP,6 -311G**) at MP2 optimizedg eometries of permethylated uniformly helical linear oligosilanes (all-w-Si n R 2n + 2 )u p to n = 16 and forb ackboned ihedral angles w = 55-1808.T he extent of s delocalization is judged by the partition ratio of the highest occupiedm olecular orbital and is reflected in the dependence of its shape and energy and of UV absorption spectra on n. The results agree with knowns pectra of all-transoid loose-helix conformers (all-[AE 165]-Si n Me 2n + 2 )a nd revealatransition at w % 908 from the "s-delocalized" limit at w = 1808 toward and closetot he physically non-realizable "s-localized" tight-helix limit w = 0w ith entirely different properties. The distinction is also obtainedi nt he Hückel Ladder Ha nd Cm odelso fs delocalization. An easy intuitive way to understand the origin of the two contrasting limits is to first view the linear chain as two subchains with alternating primary and vicinal interactions (s hyperconjugation), one consisting of the odd and the other of the even s(SiSi) bonds, andt hen allow the two subchainst oi nteract by geminal interactions (s conjugation).

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Conformational Dependence of σ‐Electron Delocalization in Linear Chains: Permethylated Oligosilanes

Bande

Michl

2009

Chemistry A European J

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The effects of sigma-electron delocalization on optical properties of saturated linear chains of permethylated oligosilanes are strongly conformation dependent. We analyze the origin of the conformational dependence of the energies of molecular orbitals and of electronic excitations in simple intuitively understandable terms by using a first-order approximation to the Hückel version of the "Ladder C" model. The analysis is supported by comparison with results of numerical calculations from time-dependent density functional theory, which agree well with experiment. To facilitate the comparison, a simple procedure has been developed that defines the overall and local fractional sigma and pi characters of a backbone molecular orbital and a fractional overall and local sigma sigma* and sigma pi* characters of an excited state for any conformation of a linear chain.

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Time-dependent density functional theory treatment of the first UV absorption band in all-transoid permethyloligosilanes SinMe2n+2 (n = 2-8, 10)

Cited by 22 publications

References 65 publications

Magnetic circular dichroism of peralkylated tetrasilane conformers

Magnetic circular dichroism of peralkylated tetrasilane conformers

Intuitive Understanding of σ Delocalization in Loose and σ Localization in Tight Helical Conformations of an Oligosilane Chain

Conformational Dependence of σ‐Electron Delocalization in Linear Chains: Permethylated Oligosilanes

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