Exceptional Molecular Hyperpolarizabilities in Twisted π‐Electron System Chromophores

Kang, Hee Kap; Facchetti, Antonio; Zhu, Ping; Jiang, Hua; Yang, Yu; Cariati, Elena; Ugo, R.; Zuccaccia, Cristiano; Macchioni, Alceo; Stern, Charlotte L.; Liu, Zhifu; Ho, Seng-Tiong; Marks, Tobin J.

doi:10.1002/ange.200501581

Cited by 30 publications

(25 citation statements)

References 36 publications

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“…The two rings in the chromophores with four ortho-methyls are twisted with dihedral angles of [54][55][56][57][58][59][60][61][62] . The dihedral angles are less than the experimental value measured by Kang et al [39] For example, the measured dihedral angle of T8 is 85. 6 , compared with the computed value of 61.23…”

Section: Geometriesmentioning

confidence: 51%

“…In the planar structure, the donor/acceptor driven charge flow is significantly favored through the conjugation paths, but is seriously blocked by the inter-ring bond in the twisted structure. An alternative electron-transfer mechanism has been proposed by several authors [39,71,72] for the twisted structures in which the overlap between the orbitals of the two fragments are reduced to facilitate electron transfer from the more electronegative part to the less electronegative part upon optical excitation, leading to large hyperpolarizabilities. Analysis based on two-state model reveals that the twisted structures possess relatively low excitation energies and large dipole moment changes from the ground to first excited states.…”

Section: First Hyperpolarizabilitymentioning

confidence: 99%

“…A number of theoretical studies [41][42][43][44] have been conducted to rationalize the origin of the enhanced responses of this new class of promising NLO chromophores. In fact, the D-p-A molecules with twisted p-electron systems have been predicted [39] to have unprecedentedly large firstorder hyperpolarizabilities, b, using the finite-field (FF) or sum-over-states approach at semi-empirical level of theory before the synthesis of tictoid molecules. Two major electronic structures, quinoid and charge-separated forms, were assigned to the tictoids.…”

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confidence: 99%

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Theoretical study of static (Hyper)polarizabilities of twisted intramolecular charge transfer chromophores

Liu¹,

Yang²,

Wang³

et al. 2011

Int J of Quantum Chemistry

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Density functional theory calculations are performed to study the (hyper)polarizabilities of a series of planar and twisted intramolecular charge transfer molecules (tictoids) with different electron-donating and electron-withdrawing groups. Both similarity and difference between the planar and twisted molecules are noted in their (hyper)polarizability variation with respect to substituent and solvent dielectric constant. When compared with dramatic enhancements resulting from geometry twist and solvent effect, substitution to D/A pairs leads to relatively moderate variation in (hyper) polarizability. In addition, tictoids with different substituents may exhibit different solvent effects in their hyperpolarizability magnitudes. Our calculations suggest that the nonlinear optical response of the tictoids could be tuned by appropriately selecting the donor/acceptor pairs and solvents.

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Section: Geometriesmentioning

confidence: 51%

Section: First Hyperpolarizabilitymentioning

confidence: 99%

mentioning

confidence: 99%

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Theoretical study of static (Hyper)polarizabilities of twisted intramolecular charge transfer chromophores

Liu¹,

Yang²,

Wang³

et al. 2011

Int J of Quantum Chemistry

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“…However, for both compounds, the large pyridinium-phenyl twist angle enhances their charge-separated character and the resulting large ground state dipole moment leads them to form aggregates. Also, upon changing the solvent used in EFISH experiments from dichloromethane to dimethylformamide, the response drops by a factor of five [6] indicating that the solvation cage may play a determinant role in the electronic properties of these chromophores.…”

Section: Introductionmentioning

confidence: 96%

Electronic responses of donor acceptor substituted twisted biphenyls

Boeglin

Barsella

Chaumeil³

et al. 2010

SPIE Proceedings

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Donor-acceptor biphenyl derivatives are particularly interesting model compounds presenting a charge transfer absorption band because the extent of conjugation, and therefore the amount of charge transfer between the substituents, may be varied by a controllable structural feature, namely the torsion angle between the two phenyl rings. This feature has become even more interesting since chromophores of strong zwitterionic character, synthesized with a twist of nearly 90°, have been shown to exhibit unprecedented quadratic responses [1], over an order of magnitude above that of the best conventional push-pull chromophores. In this context, we have investigated both experimentally and theoretically, two biphenyl based systems with varying inter-aryl angles: a nitro-piperidinyl series [2] of conventional push-pull character and a pyridinium-phenoxide series [3] of zwitterionic character. The results agree qualitatively with semiempirical simulations based on the AM1 Hamiltonian [4] used with the COSMO solvation model [5]. For the first series, the decrease in quadratic response with increasing dihedral angle indicates that oscillator strength loss is the dominant factor. In the second series, the corresponding increase in quadratic response points to the change in dipole moment upon excitation as the leading effect. Here, we will analyze to what extent the more ab initio electronic structure calculations based on the density functional theory may provide more quantitative results in spite of the problems they face in the description of charge transfer systems.

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“…For molecules of type II we will show that disruption of the π-conjugation via a sterically induced molecular twisting results in unusual molecular characteristics and unprecedented hyperpolarizabilities (μβ values as high as -466,000 × 10 -48 esu at 1907 nm) [4]. Guest-host poled polymers containing these chromophores reveal very large electro-optic coefficients (r 33 ) up to 320 pm/V at 1310 nm.…”

mentioning

confidence: 98%

New building blocks and growth processes for high-performance self-assembled electro-optic materials

Facchetti

Jiang

et al. 2006

2006 Conference on Lasers and Electro-Optics and 2006 Quantum Electronics and Laser Science Conference

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The design rationale, synthesis, and characteristics of organic chromophores exhibiting very large EO response is presented along with new methodologies to assembled them in a noncentrosymmetric fashion.Electro-optic (EO) materials based on second-order NLO-active organic small molecules have been widely investigated for optoelectronic and photonic technologies such as high-speed optical communications, integrated optics, and optical data processing and storage [1]. These materials offer significant advantages over conventional inorganic crystalline materials, such as facile processing, lower dielectric constants, and higher electro-optic coefficients. Ultra-high-speed (>100 GHz) EO modulation in organic material systems has been demonstrated to be feasible. Crucial synthetic challenges for large bulk EO response in such materials are that individual chromophore components have large molecular hyperpolarizabilities (β) and that they be arranged in a noncentrosymmetric architecture. Large β values and bulk polar order are therefore the two prerequisites for large EO response.The design rationale, synthesis, and molecular properties of organic chromophores enabling very large molecular nonlinearities and bulk EO responses is presented along with new processes for self-assembling them in a noncentrosymmetric fashion. The general structure of these donor-π-acceptor/unconventional molecules can be summarized by the formulas I -III. N R X n N X N H N OH O twist angle Θ H-bond acceptor/donor II III CN CN X = O ; R R N N N N SiMe 2 t-Bu SiMe 2 t-Bu Si I X = NMe, S Cl I ClMolecules of type I in combination with octachlorotrisiloxane deprotecting reagent/interlayer precursor allow the realization of an efficient, expeditious siloxane-based layer-by-layer assembly process for the formation of intrinsically polar organic electro-optic thin films on glass, Si-SiO 2 , and ITO substrates [2]. Chromophore monolayer deposition from solution reaches completion in about 15 min at 55 C. The adherent, structurally regular assemblies CThI1.pdf 1-55752-813-6/06/$25.00 ©2006 IEEE

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Exceptional Molecular Hyperpolarizabilities in Twisted π‐Electron System Chromophores

Cited by 30 publications

References 36 publications

Theoretical study of static (Hyper)polarizabilities of twisted intramolecular charge transfer chromophores

Theoretical study of static (Hyper)polarizabilities of twisted intramolecular charge transfer chromophores

Electronic responses of donor acceptor substituted twisted biphenyls

New building blocks and growth processes for high-performance self-assembled electro-optic materials

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