Structure-Photochemical Function Relationships in Nitrogen-Containing Heterocyclic Aromatic Photobases Derived from Quinoline

Alamudun, Sophya; Tanovitz, Kyle; Fajardo, April; Johnson, Kaitlind; Pham, Andy V.; Araghi, Tina Jamshidi; Petit, Andrew S.

doi:10.26434/chemrxiv.11312642

Cited by 2 publications

(6 citation statements)

References 20 publications

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“…As illustrated in Table S3 in the Supporting Information, the strong photobase 5-aminoquinoline has ΔΔG = −14.3 kcal/mol, the weak photobase 5-cyanoquinoline has ΔΔG = −4.4 kcal/ mol, and 4-aminoquinoline, which is a stronger base in the ground state, has ΔΔG = 2.2 kcal/mol. 22 For the cis-and trans-conformers of MPDA, the calculated ΔΔG values of 17.3 and 17.9 kcal/mol demonstrate that electronic excitation causes a large decrease in the basicity of the diazo carbon of MDPA. This thermodynamic analysis, in conjunction with the results presented in Figure 2 and Tables S1 and S2, demonstrates that the blue-light-induced O−H functionalization of alcohols by MDPA does not occur through photobasicity.…”

Section: ■ Results and Discussionmentioning

confidence: 90%

“…The Forster cycle has been used by us and others to relate the thermodynamic driving force for photobasicity, ΔG*, to ground-state energetics and spectroscopic observables 22,24,38…”

Section: = + − G E H Tsmentioning

confidence: 99%

“…The adiabatic energy gaps required for calculating ΔΔG were obtained using the same computational procedure as used in our previous studies of N-heterocycle photobases. 22,23 Specifically, the geometry optimizations used the ωB97X-D exchange-correlation functional with a (99,590) integration grid, a def2-SVPD basis set, and a CPCM solvation model. The excited-state geometry optimizations were performed within the Tamm Dancoff approximation (TDA).…”

Section: ■ Acknowledgmentsmentioning

confidence: 99%

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Computationally Probing the Mechanism of the Blue-Light-Driven O–H Functionalization of Alcohols by Aryldiazoacetates: Photobasicity or Carbene Chemistry

2022

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Photochemistry provides green alternatives to traditional reaction conditions and opens up routes toward products that are otherwise difficult to make. Recent work by Koenigs and co-workers demonstrated the blue-light-driven O–H functionalization of alcohols by aryldiazoacetates. Based on spectroscopic and computational analyses, Koenigs and co-workers demonstrated that the alcohols form a hydrogen-bonding complex with aryldiazoacetates prior to the light absorption, with the strength of hydrogen bonding correlated with the product yield. Because methyl phenyldiazoacetate (MPDA) was observed to preferentially react with alcohols over cyclopropanation with styrene, the reaction was speculated to occur via excited-state proton transfer, with MPDA acting as a photobase. In this paper, we use time-dependent density functional theory to show that the electronic excited state of aryldiazoacetates is inconsistent with photobasicity. Instead, we argue that the reaction proceeds via a carbene intermediate generated through the photolysis of the aryldiazoacetate. Using density functional theory, we demonstrate that the reaction between the singlet state of the carbene intermediate and the alcohol is thermodynamically favorable and very fast. Moreover, we provide a rationalization for the experimentally observed preference for O–H functionalization with alcohols over cyclopropanation with alkenes. Overall, this work provides a refined mechanistic understanding of an interesting photochemical transformation.

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Section: ■ Results and Discussionmentioning

confidence: 90%

“…The Forster cycle has been used by us and others to relate the thermodynamic driving force for photobasicity, ΔG*, to ground-state energetics and spectroscopic observables 22,24,38…”

Section: = + − G E H Tsmentioning

confidence: 99%

Section: ■ Acknowledgmentsmentioning

confidence: 99%

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Computationally Probing the Mechanism of the Blue-Light-Driven O–H Functionalization of Alcohols by Aryldiazoacetates: Photobasicity or Carbene Chemistry

2022

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“…We used electronic structure calculations to further characterize the Lewis photobasicity of 5-R-quinolines. Our approach is similar to the one used by the Petit group studying proton transfer energetics of a series of photobases 37,38 with some small modifications made to suit the study of dative bond complexes. Their computational results were shown to correlate quite well with experimental values for the excitedstate drive for proton transfer in quinoline photobases.…”

Section: Methodsmentioning

confidence: 99%

“…Their computational results were shown to correlate quite well with experimental values for the excitedstate drive for proton transfer in quinoline photobases. 37 We will outline our procedure here and refer the reader to Petit's prior work for a more detailed discussion. Paralleling the experimental work, a computational Forster cycle requires the calculation of three energies: the 0−0 gap between the ground state and the photobasic electronic ), the 0−0 gap between the ground state and the photobasic electronic state of the adducted quinoline (ΔE 00 adduct ), and the ground-state energy for adduct dissociation (ΔE GS ).…”

Section: Methodsmentioning

confidence: 99%

Can Brønsted Photobases Act as Lewis Photobases?

Voegtle

Dawlaty

2022

J. Am. Chem. Soc.

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Dative bonding or Lewis acid–base chemistry underpins a large number of chemical phenomena in a variety of fields, such as catalysis, metal–ligand interactions, and surface chemistry. Developing light-controlled Lewis acid–base interactions could offer a new way of controlling and understanding such phenomena. Photoinduced proton transfer, that is, excited-state Brønsted acidity and basicity, has been extensively studied and applied. Here, in direct analogy to excited-state Brønsted basicity, we show that exciting a photobasic molecule with light generates a thermodynamic drive for the transfer of a Lewis acid from a donor to a photobasic molecule. We have used the archetypal BF3 as our Lewis acid and our photoactive Lewis bases are a family of quinolines, which are known Brønsted photobases as well. We have constructed the experimental Förster cycle for this system and have verified it computationally to demonstrate that a significant drive (0.2–0.7 eV) exists for the transfer of BF3 to a photoexcited quinoline. The magnitude of this drive is similar to those reported for Brønsted photobasicity in quinolines. Computational results from TDDFT and energy decomposition analysis show that the origin of such an effect is similar to the Brønsted photoactivity of these molecules, in that they follow the Hammett parameter of substituent groups. These results suggest that photobases may be capable of controlling the chemical phenomena beyond proton transfer and may open opportunities for a new handle in photocatalysis.

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Structure-Photochemical Function Relationships in Nitrogen-Containing Heterocyclic Aromatic Photobases Derived from Quinoline

Cited by 2 publications

References 20 publications

Computationally Probing the Mechanism of the Blue-Light-Driven O–H Functionalization of Alcohols by Aryldiazoacetates: Photobasicity or Carbene Chemistry

Computationally Probing the Mechanism of the Blue-Light-Driven O–H Functionalization of Alcohols by Aryldiazoacetates: Photobasicity or Carbene Chemistry

Can Brønsted Photobases Act as Lewis Photobases?

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