Metastable Chiral Azobenzenes Stabilized in a Double Racemate

Mohan, Amalu; Sasikumar, Devika; Bhat, Vinayak; Hariharan, Mahesh

doi:10.1002/anie.201910687

Cited by 17 publications

(14 citation statements)

References 65 publications

(70 reference statements)

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“…Overlap between the electrophilic and nucleophilic regions of interacting halogen atoms plays a pivotal role in assembling T2 in a self-complementary manner which results in unbounded 2D zipper assembly. SAPT(0) analysis was employed to explore the stability of the intermolecular interactions 53 modeling molecular zippers of NTB 2 . SAPT(0) provided a quantitative picture of the interactions by decomposing the total interaction energy into physically meaningful components (electrostatic, exchange, induction, and dispersion) (Table 1).…”

Section: ■ Results and Discussionmentioning

confidence: 99%

Atom-Efficient Halogen–Halogen Interactions Assist One-, Two-, and Three-Dimensional Molecular Zippers

et al. 2021

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Unprecedented multimodal weak interactions are quintessential to create novel supramolecular topologies. Among the plethora of weak interactions, halogen− halogen (X•••X) interactions offer innovative possibilities for the design of multidimensional scaffolds. Herein, we chronicle the state-of-the-art 1D, 2D, and 3D zipper motifs steered by distinct interhalogen interactions, revealing the potential of halogen bonding in engineering biomimetic molecular assemblies. Recurring units of Br 4 synthon, framed by type I and type II atom efficient X•••X interactions in a dibromonaphthathiazole derivative, 2,4-dibromo-5ethoxynaphtho[1,2-d]thiazole (NTB 2 ), forges the molecular zipper. On the basis of the semiclassical Marcus theory of charge transport, the NTB 2 zipper assembly displays selective electron transport along the type II X•••X bonded direction. Band structure analysis classified the crystalline NTB 2 as a wide band gap semiconductor with a band gap of 2.80 eV, respectively. The robustness of the X•••X mediated zipper motif opens up new avenues in the development of advanced functional materials.

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Section: ■ Results and Discussionmentioning

confidence: 99%

Atom-Efficient Halogen–Halogen Interactions Assist One-, Two-, and Three-Dimensional Molecular Zippers

et al. 2021

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“…Aromaticity changes along the T 1 potential energy surface of stilbene have been reported with an aromatic relaxed T 1 state exhibiting a twisted geometry [21] . Recently our group could capture a similar twisted geometry of azobenzene in the crystalline state for the first time wherein the twist was induced by the host [22] …”

Section: Introductionmentioning

confidence: 84%

“…[21] azobenzene in the crystalline state for the first time wherein the twist was induced by the host. [22] Along with our previous work of antiaromaticity relief in triplet excimer of linear acenes appealing to the potential application in supramolecular architectures, [23] we were also eager to perceive monomeric excited-state processes in terms of aromaticity. Our persistent efforts aided in elucidating the Z/ E thermal isomerization of one of the most widely used molecular switches, azobenzene (Ab) through the lens of aromaticity.…”

Section: Introductionmentioning

confidence: 86%

Retaining Hückel Aromaticity in the Triplet Excited State of Azobenzene

2022

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The implication of the potential concept of aromaticity in the relaxed lowest triplet state of azobenzene, an efficient molecular switch, using elementary aromaticity indices based on magnetic, electronic, and geometric criteria has been discussed. Azobenzene exhibits a major Hückel aromatic character retained in the diradical lowest relaxed triplet state (T1) by virtue of a twisted geometry with partial delocalization of unpaired electrons in the perpendicular p‐orbitals of two nitrogen atoms to the corresponding phenyl rings. The computational analysis has been expanded further to stilbene and N‐diphenylmethanimine for an extensive understanding of the effect of closed‐shell Hückel aromaticity in double‐bond‐linked phenyl rings. Our analysis concluded that stilbene has Hückel aromatic character in the relaxed T1 state and N‐diphenylmethanimine has a considerable Hückel aromaticity in the phenyl ring near the carbon atom while a paramount Baird aromaticity in the phenyl ring near the nitrogen atom of the C=N double bond. The results reveal the application of excited‐state aromaticity as a general tool for the design of molecular switches.

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“…In the field of biomedicine, this mainly involves the regulation of mechanical and optical properties, and the self‐assembly process of supramolecular systems. [ 271 ] The photoisomerization of azobenzene also provides an effective way to convert light energy into mechanical driving force from a nano to a macro level, and provides insight for manufacturing optical driving biomaterials. [ 272 ]…”

Section: Main Specific Applications Of Azobenzenementioning

confidence: 99%

Advances in Application of Azobenzene as a Trigger in Biomedicine: Molecular Design and Spontaneous Assembly

et al. 2021

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Azobenzene is a well‐known derivative of stimulus‐responsive molecular switches and has shown superior performance as a functional material in biomedical applications. The results of multiple studies have led to the development of light/hypoxia‐responsive azobenzene for biomedical use. In recent years, long‐wavelength‐responsive azobenzene has been developed. Matching the longer wavelength absorption and hypoxia‐response characteristics of the azobenzene switch unit to the bio‐optical window results in a large and effective stimulus response. In addition, azobenzene has been used as a hypoxia‐sensitive connector via biological cleavage under appropriate stimulus conditions. This has resulted in on/off state switching of properties such as pharmacology and fluorescence activity. Herein, recent advances in the design and fabrication of azobenzene as a trigger in biomedicine are summarized.

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Metastable Chiral Azobenzenes Stabilized in a Double Racemate

Cited by 17 publications

References 65 publications

Atom-Efficient Halogen–Halogen Interactions Assist One-, Two-, and Three-Dimensional Molecular Zippers

Atom-Efficient Halogen–Halogen Interactions Assist One-, Two-, and Three-Dimensional Molecular Zippers

Retaining Hückel Aromaticity in the Triplet Excited State of Azobenzene

Advances in Application of Azobenzene as a Trigger in Biomedicine: Molecular Design and Spontaneous Assembly

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