Azobenzene‐Substituted Triptycenes: Understanding the Exciton Coupling of Molecular Switches in Close Proximity

Kunz, Anne; Oberhof, Nils; Scherz, Frederik; Martins, Leon; Dreuw, Andreas; Wegner, Hermann A.

doi:10.1002/chem.202200972

Cited by 12 publications

(8 citation statements)

References 54 publications

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“…Generally, there is not a standard definition of the term developing azo dye because it can be synthesized from any fiber. However, more than 100.000 different types of azo dye are currently used in recent technology and industrial applications [2] such as in biomedical applications [3], catalyst [4], laser technology [5], industrial dyes [6], degradation material [7], etc.…”

Section: -({4-[bis(2-cyanoethylmentioning

confidence: 99%

Quantum Chemical Characterization of 4-({4-[Bis(2-Cyanoethyl)Amino]Phenyl}Diazinyl)Benzene Sulfonamide by Ab-Initio Calculation

Ayun¹,

Tasli²,

Kart³

et al. 2022

iij

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4-({4-[Bis(2-cyanoethyl)amino]phenyl}diazinyl)benzene sulfonamide is the azo dye material which has general application in the textile industry. Experimentally, it has been synthesized and geometrically characterized by G. Gervasio et al. In this study, the theoretical analysis has been calculated by using the ab-initio method based on the Density Functional Theory/B3LYP/6-311G(d,p) to characterize the structural, spectroscopy, and electronic properties of the title azo dye. Its molecular geometries are in good agreement with those of available experimental data. 129 vibrational modes have been specified with stretching, in-plane-bending, out-of-plane-bending, and torsion vibration modes by the Potential energy Distribution analysis. The ultraviolet spectra appear in a single peak for six common solvation at 429 nm. The Gauge-Invariant Atomic Orbital approach has been applied to predict the chemical shifts of 1H and 13C NMR only in DMSO solvation. The electronic properties have been investigated such as the energy bandgap (3.34 eV), ionization potential energy (6.24 eV), electron affinity (2.90 eV), electronegativity (4.57 eV), and chemical hardness (1.67 eV) by using the Frontier Molecular Orbital Theory from the energy interaction of the Lowest Unoccupied Molecular Orbital and Highest Occupied Molecular Orbital. The characterization of the title azo dye is conducted theoretically for the first time in this study.

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Section: -({4-[bis(2-cyanoethylmentioning

confidence: 99%

Quantum Chemical Characterization of 4-({4-[Bis(2-Cyanoethyl)Amino]Phenyl}Diazinyl)Benzene Sulfonamide by Ab-Initio Calculation

Ayun¹,

Tasli²,

Kart³

et al. 2022

iij

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“…Excited electronic states play an important role in many chemical and physical processes. For multiple chromophore molecules found in the liquid, solid state, and sometimes gas phase, electronic excitations are affected by the interaction between excited states, known as the excitonic coupling. − It can be described in Förster resonance energy-transfer (FRET) models …”

Section: Introductionmentioning

confidence: 99%

Analysis of Site Energies and Excitonic Couplings: The Role of Symmetry and Polarization

Fedorov

2024

J. Phys. Chem. A

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An excitonic coupling model is developed based on an equation-of-motion coupled cluster combined with the fragment molecular orbital method. The effects of polarization and excitonic coupling on the splitting of quasi-degenerate levels in systems containing multiple chromophores are elucidated on dimers of formaldehyde, water, formic acid, hydrogen fluoride, and carbon monoxide. It is shown that the level structure is mainly determined by the mutual polarization of chromophores and to a lesser extent by the excitonic coupling. The role of symmetry in excitonic coupling in dimers is discussed. The excitonic coupling between all residues in the photoactive yellow protein (PDB: 2PHY) is analyzed.

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“…This inherent flexibility in the choice of light source significantly amplifies its versatility when compared to alternative photoswitching molecules, which often require a specific wavelength of light to achieve efficient isomerization. This isomerization impacts electron transport and spin polarization, making the functional material-azobenzene single-molecule junction an intriguing platform for exploring the role of molecular structure in spin-polarized electron transmission. The fundamental concept in spin-polarized transmission is that a molecule’s electronic structure can be affected by its conformation and can also impact the spin properties of the electrons.…”

Section: Introductionmentioning

confidence: 99%

Spintronics on Demand: Optically Tunable Kondo-Type Phenomena in Germanene-Azobenzene Single-Molecule Junctions

Sarmah,

Sarma,

Nakajima

et al. 2024

J. Phys. Chem. C

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This study delves into the exploration of AZB–germanene composite systems, which are known for their intriguing characteristics, including the emergence of Kondo features and the precise manipulation of electronic spin induced by light exposure. The spin-polarized signature within trans-AZB exerts a significant influence on the band structure near the Fermi level, highlighting the critical role of conformational changes within the AZB component in regulating the magnetoelectronic coupling within the composite system. The research systematically analyzed the intricate interplay of electronic states within these systems with a specific focus on the potential observation of Kondo-like resonance in the trans-AZB–Ge system, resulting in the development of a spin-polarized electronic current within the junction. Theoretical insights suggest that the presence of a Kondo-like effect has the potential to significantly impact the electronic and magnetic properties of the system, making it a promising avenue for precise electronic control within the field of molecular electronics.

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Azobenzene‐Substituted Triptycenes: Understanding the Exciton Coupling of Molecular Switches in Close Proximity

Cited by 12 publications

References 54 publications

Quantum Chemical Characterization of 4-({4-[Bis(2-Cyanoethyl)Amino]Phenyl}Diazinyl)Benzene Sulfonamide by Ab-Initio Calculation

Quantum Chemical Characterization of 4-({4-[Bis(2-Cyanoethyl)Amino]Phenyl}Diazinyl)Benzene Sulfonamide by Ab-Initio Calculation

Analysis of Site Energies and Excitonic Couplings: The Role of Symmetry and Polarization

Spintronics on Demand: Optically Tunable Kondo-Type Phenomena in Germanene-Azobenzene Single-Molecule Junctions

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