Enhancement of molecular polarizabilities by the push-pull mechanism; a DFT study of substituted benzene, furan, thiophene and related molecules

Hinchliffe, Alan; Mkadmh, Ahmed M.; Nikolaidi, Beatrice; Soscún, Humberto; Abu-Awwad, Fakhr M.

doi:10.2478/s11532-006-0037-x

Cited by 8 publications

(10 citation statements)

References 18 publications

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“…The long 26-NDC linker decreases the wettability of the surface (higher contact angle). Furthermore, the presence of -NH 2 , and -OH groups can increase the polarizability and thus its wettability, 28,29 which is consistent with the measured contact angles for Zr-2A-BDC and Zr-25D-BDC. Additionally, we show an evolution of the contact angle versus time.…”

Section: Wetting Characteristicssupporting

confidence: 84%

Photoactive Zr-aromatic hybrid thin films made by molecular layer deposition

et al. 2022

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Section: Wetting Characteristicssupporting

confidence: 84%

Photoactive Zr-aromatic hybrid thin films made by molecular layer deposition

et al. 2022

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“…18 nm/NS. The synergistic effect found here is analogous to the positive enhancement in the molecular polarizability of benzene by certain activating functional groups …”

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confidence: 58%

“…The synergistic effect found here is analogous to the positive enhancement in the molecular polarizability of benzene by certain activating functional groups. 37 In assemblies with multiple NSs, the respective placement of NSs on the NP must dictate the nature of plasmonic coupling and the resulting spectral characteristics of the assembly. In contrast to the uniform distribution of NSs, shown in Figure 5, we found some instances of NSs asymmetrically distributed around the NP sides (Figure 6A,B).…”

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confidence: 99%

Regioselective Plasmonic Coupling in Metamolecular Analogs of Benzene Derivatives

2014

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In analogy with benzene-derived molecular structures, we construct plasmonic metamolecules by attaching Au nanospheres to specific sites on a hexagonal Au nanoplate. We employ a ligand exchange strategy that allows regioselective control of nanosphere attachment and study resulting structures using correlated electron microscopy/optical spectroscopy at the single-metamolecule level. We find that plasmonic coupling within the resulting assembly is strongly dependent on the structure of the metamolecule, in particular the site of attachment of the nanosphere(s). We also uncover a synergy in the polarizing effect of multiple nanospheres attached to the nanoplate. Regioselective control of plasmonic properties demonstrated here enables the design of novel structure-dependent electromagnetic modes and applications in three-dimensional spatial nanosensors.

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“…A particular case of longstanding interest is the barrier to rotation in push−pull furfural systems, especially due to their importance as components in many biological redox centers and synthetic molecular devices. − Moreover, these systems have associated experimental as well as computational challenges . For example, the very small energy difference between the cis and trans isomers, the possibility for secondary interactions in some of the analogues as well as the strong solvent dependencies across a small range of dielectric (particularly for the parent furan-2-carbaldehyde system), creates particular challenges for both experimental as well as computational predictions.…”

Section: Illustrative Example: Ground State Conformational Dynamics O...mentioning

confidence: 99%

Implementation and Optimization of DFT-D/COSab with Respect to Basis Set and Functional: Application to Polar Processes of Furfural Derivatives in Solution

Peverati

Baldridge

2009

J. Chem. Theory Comput.

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The implementation, optimization, and performance of DFT-D, including the effects of solvation, has been tested on applications of polar processes in solution, where dispersion and hydrogen bonding is known to be involved. Solvent effects are included using our ab initio continuum solvation strategy, COSab, a conductor-like continuum solvation model, modified for ab initio in the quantum chemistry program GAMESS. Structure and properties are investigated across various functionals to evaluate their ability to properly model dispersion and solvation effects. The commonly used S22 set with accurate interaction energies of organic complexes has been used for parametrization studies of dispersion parameters and relevant solvation parameters. Dunning's correlation consistent basis sets, cc-pVnZ (n = D, T), are used in the optimization, together with the Grimme B97-D exchange-correlation functional. Both water (ε = 78.4) and ether (ε = 4.33) environments are considered. Optimized semiempirical dispersion correction parameters and solvent extent radii are proposed for several functionals. We find that special parametrization of the semiempirical dispersion correction when used together in the DFT-D/COSab approach is not necessary. The global performance is quite acceptable in terms of chemical accuracy and suggests that this approach is a reliable as well as economical method for evaluation of solvent effects in systems with dispersive interactions. The resulting theory is applied to a group of push-pull pyrrole systems to illustrate the effects of donor/acceptor and solvation on their conformational and energetic properties.

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Enhancement of molecular polarizabilities by the push-pull mechanism; a DFT study of substituted benzene, furan, thiophene and related molecules

Cited by 8 publications

References 18 publications

Photoactive Zr-aromatic hybrid thin films made by molecular layer deposition

Photoactive Zr-aromatic hybrid thin films made by molecular layer deposition

Regioselective Plasmonic Coupling in Metamolecular Analogs of Benzene Derivatives

Implementation and Optimization of DFT-D/COSab with Respect to Basis Set and Functional: Application to Polar Processes of Furfural Derivatives in Solution

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