Molecular Origins of the High-Performance Nonlinear Optical Susceptibility in a Phenolic Polyene Chromophore: Electron Density Distributions, Hydrogen Bonding, and ab Initio Calculations

Lin, Tze-Chia; Cole, Jacqueline M.; Higginbotham, Andrew; Edwards, Alison J.; Piltz, Ross O.; Pérez‐Moreno, Javier; Seo, Ji‐Youn; Lee, Seung−Chul; Clays, Koen; Kwon, O‐Pil

doi:10.1021/jp400648q

Cited by 34 publications

(40 citation statements)

References 67 publications

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“…In this context, the higher second and third order NLO properties of simple organic molecular materials have been extensively studied. [12][13][14][15] Past few decades have witnessed developments in terms of synthesis of a huge number of organic π conjugated molecules with suitable molecular design strategies for better NLO materials. 16 Many of these molecules bear donor and acceptor groups separated by a conjugated bridge (D-π-A) with a push-pull type of arrangement.…”

Section: Introductionmentioning

confidence: 99%

Fluorescent vinyl and styryl coumarins: A comprehensive DFT study of structural, electronic and NLO properties

2017

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Nonlinear optical properties of 3-styryl and 3-vinyl coumarin dyes have been investigated with Density Functional Theory (DFT) using global hybrid (GH) and range-separated hybrid (RSH) functionals. The performance of GHs-B3LYP, BHHLYP, PBE0, M06, M06L, M062X, and M06HF and RSHs-CAM-B3LYP, HISSbPBE, HSEH1PBE, wB97, wB97X, and wB97XD in combination with 6-311++G(d,p) basis set has been analyzed. Estimated (hyper) polarizability (α 0 , β 0) obtained from the GHs-M06, M062X and PBE0 are in agreement with each other. The RSHs-wB97 and wB97X estimate very close values of β 0. The β 0 value of 3-styryl and 3-vinyl coumarins reaches the maximum as the bond length alternation and bond order alternation parameters tend to zero. Natural bond orbital analysis shows there is extensive charge transfer in the excited state leading to large value of β 0. The vibrational contribution to α 0 and β 0 is significantly less when the donor is methoxy group and acceptor is nitro group in the 3-styryl coumarin. The dye, (E)-7-(diethylamino)-3-(4nitrostyryl)-2H-chromen-2-one (3c) is found to give the highest NLO response. An increasing electrophilicity originating from the decreased HOMO-LUMO band gap leads to an increase in α 0 and β 0 in all the cases.

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Section: Introductionmentioning

confidence: 99%

Fluorescent vinyl and styryl coumarins: A comprehensive DFT study of structural, electronic and NLO properties

2017

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“…Phase disruption is proposed as a new general principle for the design of molecules, nanowires and any quasi-1D quantum system with large intrinsic response and does not require charge donor-acceptors at the ends. © The design and realization of ultrafast nonlinear optical materials with large responses to optical frequency electric fields remains an active field of pure and applied research [1][2][3][4]. To date, no general design rules for obtaining large nonlinearities from any structure have been articulated, and the response of materials remains well below that allowed by quantum physics.…”

mentioning

confidence: 99%

Phase disruption as a new design paradigm for optimizing the nonlinear-optical response

2015

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The intrinsic optical nonlinearities of linear structures, including conjugated chain polymers and nanowires, are shown to be dramatically enhanced by the judicious placement of a charge diverting path sufficiently short to create a large phase disruption in the dominant eigenfunctions along the main path of probability current. Phase disruption is proposed as a new general principle for the design of molecules, nanowires and any quasi-1D quantum system with large intrinsic response and does not require charge donor-acceptors at the ends. © The design and realization of ultrafast nonlinear optical materials with large responses to optical frequency electric fields remains an active field of pure and applied research [1][2][3][4]. To date, no general design rules for obtaining large nonlinearities from any structure have been articulated, and the response of materials remains well below that allowed by quantum physics. In this letter, we propose a general principle that may explain why modern molecules fall short of their potential and use it to demonstrate simple structures with nonlinear responses approaching the physical limits.The off-resonance electronic nonlinear optical response of a molecule is completely determined by its energy spectrum and transition moments. Normalized to its maximum value, the sum over states expression for the intrinsic first hyperpolarizability along the x-axis may be written as [5] where the sum is over all states, x nℓ is the n, ℓ element of the position matrix withx = x − x 00 , E n0 = E n − E 0 is the difference in energy of eigenstates n and 0, N is the number of electrons and m their mass. We include as many as 100 energy eigenstates to calculate β, but systems with large β are always well approximated using only three states. For brevity, we focus on the first hyperpolarizability, though our results also hold for the second hyperpolarizability, γ xxxx . For the remainder of this letter, all hyperpolarizabilities are divided by their maximum values and represent intrinsic tensor properties. It is evident from Eqn.(1) that a system optimized for nonlinear optics will necessarily have eigenfunctions with a large degree of overlap as well as a large change of dipole moment between contributing levels. This is an essential trade-off to achieve a large response. It is generally recognized that the hyperpolarizabilities of most molecules fall at least 30 times short of the limits. [5,6]. Monte Carlo simulations discovered the optimum energy spectrum for such molecules and provided a strong indicator of the origin of the gap [7]. Optimization of the effective potential energy an electron experiences across the main direction of a quasi-linear molecule showed that the hyperpolarizabilities may be increased by tuning a few parameters [8], by modulation of conjugation along a chain [9], or by donor-acceptor substitution and insertion of spacers [10]. However, there is no general rule about how to construct the ideal potential energy profile across a molecule to maximize the nonlinea...

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“…The molecular structures of 2a-c, 2e, and 2f and their packing arrangements are shown in Figures 1, 2, 3, 4, and 5. As shown in Table 5, the torsion angles between double bonds and adjacent carbonyl [θ (0,1,2,3) ] groups are distributed from 41 to 50°, and the torsion angle between the double bonds with the two adjacent aryl rings [θ (2,3,4,5) and θ (6,7,8,9) ] are in the 27-42°and 16-89°range, respectively. Another noteworthy feature of these molecules in the crys- tal is torsion conformation, which is due to the large steric hindrance of the aryl groups linking to the double bonds.…”

Section: Crystal Structures Of Decatetraene Diketonesmentioning

confidence: 99%

“…[5][6][7][8] Recently, these compounds have attached growing interest as a result of their unique electronic structures and optoelectronic properties. [9][10][11] Considerable efforts have been devoted to the development of synthetic approaches to polyene derivatives. [12][13][14] Traditional methods are based on Wittig and Horner-Emmons-Wadsworth conversions [15,16] and transition-metal-(especially Pd)-catalyzed cross-coupling reactions.…”

Section: Introductionmentioning

confidence: 99%

One‐Step Stereoselective Synthesis of (2Z,4Z,6Z,8Z)‐Decatetraene Diketone from Pyrylium Salts

Yang

Gao

et al. 2013

Eur J Org Chem

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A strategy for the stereoselective synthesis of (2Z,4Z,6Z,8Z)‐decatetraene diketone by the one‐step metal reduction of pyrylium salts is described. Reduction of α‐active pyrylium salts (at least one H at the α‐C positon) leads to only linear decatetraene diketone derivatives, whereas reduction of α‐non‐active pyrylium salts (no H at the α‐C position) generates two unexpected structures and one linear decatetraene diketone. The reaction conditions were optimized, and a reaction mechanism was proposed. Single‐crystal structures of decatetraene diketone derivatives demonstrate the twisted configuration of the backbones and the all‐(Z) geometry of the double bonds. In addition, the thermal, optical, and electrochemical properties of these compounds were studied in detail.

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Molecular Origins of the High-Performance Nonlinear Optical Susceptibility in a Phenolic Polyene Chromophore: Electron Density Distributions, Hydrogen Bonding, and ab Initio Calculations

Cited by 34 publications

References 67 publications

Fluorescent vinyl and styryl coumarins: A comprehensive DFT study of structural, electronic and NLO properties

Fluorescent vinyl and styryl coumarins: A comprehensive DFT study of structural, electronic and NLO properties

Phase disruption as a new design paradigm for optimizing the nonlinear-optical response

One‐Step Stereoselective Synthesis of (2Z,4Z,6Z,8Z)‐Decatetraene Diketone from Pyrylium Salts

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