Photochemistry of 2-Naphthoyl Azide. An Ultrafast Time-Resolved UV–Vis and IR Spectroscopic and Computational Study

Kubicki, Jacek; Zhang, Yunlong; Vyas, Shubham; Burdziński, Gotard; Luk, Hoi Ling; Wang, Jin; Xue, Jingling; Peng, Huo Lei; Pritchina, Elena A.; Sliwa, Michel; Buntinx, G.; Gritsan, Nina P.; Hadad, Christopher M.; Platz, Matthew S.

doi:10.1021/ja109098w

Cited by 52 publications

(101 citation statements)

References 49 publications

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“…Nitrenes are best described as electron‐deficient reactive intermediates and their reactivity is controlled by the nature of their substituents and their electron configuration . Generally, the triplet configuration of nitrenes is more stable than the corresponding singlet configuration, although nitrenes such as acylnitrenes have singlet ground states . Electron‐donating substituents stabilize triplet nitrene intermediates, whereas electron‐withdrawing substituents render them more reactive.…”

Section: Introductionmentioning

confidence: 99%

Photolysis of 3,5‐diphenylisoxazole in argon matrices

Sriyarathne

Sarkar

Hatano

et al. 2016

J of Physical Organic Chem

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Broadband irradiation of 3,5‐diphenylisoxazole 1 in an argon matrix results in formation of azirine 3. Further irradiation of the matrix reduces the amount of azirine 3 with concurrent formation of ylide 4. Thus, it is theorized that the conversion of isoxazole 1 to azirine 3 goes through a triplet vinylnitrene 2 that does not intersystem cross to ketenimine 6. Hence, the reactivity of triplet vinylnitrene 2 is different from similar vinylnitrene intermediates with α‐methyl substituents that intersystem cross to form corresponding ketenimines. Density functional theory calculations support the notion that the conjugation of the α‐phenyl group to the vinylnitrene moiety in vinylnitrene 2 renders it more flexible than vinylnitrenes with α‐methyl substituents, and therefore, vinylnitrene 2 intersystem crosses to azirine 3, rather than ketenimine 6. Copyright © 2016 John Wiley & Sons, Ltd.

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Section: Introductionmentioning

confidence: 99%

Photolysis of 3,5‐diphenylisoxazole in argon matrices

Sriyarathne

Sarkar

Hatano

et al. 2016

J of Physical Organic Chem

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“…Very recently, we reported the results of an fs time‐resolved UV–vis and IR study of the photochemistry of 2‐NpCON 3 in a series of solvents. Polar solvents were found to accelerate the S 1 state's decay significantly.…”

Section: Introductionmentioning

confidence: 99%

An ultrafast time‐resolved infrared and UV–vis spectroscopic and computational study of the photochemistry of acyl azides

Vyas

Kubicki

Luk

et al. 2012

J of Physical Organic Chem

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The photochemistry of pivaloyl, benzoyl, 4‐phenylbenzoyl, and 2‐anthroyl azides has been studied using femtosecond (fs) time‐resolved infrared (TRIR) and UV–vis spectroscopy and interpreted with the aid of computational chemistry. Density functional theory calculations revealed a significant difference in the nature of the lowest singlet excited state for these carbonyl azides. The lowest singlet excited states (S1) of p‐phenylbenzoyl and 2‐anthroyl azides are (π,π*) in nature, while the pivaloyl and benzoyl azides S1 states involve (n,π*) excitations. Nevertheless, for all acyl azides studied here, a similar, and intense, IR band at about 2100 cm−1 has been detected in the ultrafast TRIR experiments following 270 nm excitation. These bands were shifted to lower energy by about 100 cm−1 relative to the N3 stretching mode for the ground states of these azides. These 2100 cm−1 vibrational bands were assigned to the S1 states of acyl azides in agreement with density functional theory calculations. The decay of the acyl azide S1 states was described by bi‐exponential functions. The fast component was attributed to the decay of the hot S1 state and the longer component to the decay of the thermally relaxed S1 state. A strong and broad transient absorption in the 350–650 nm spectral range was observed in the fs UV–vis experiments for p‐phenylbenzoyl and 2‐anthroyl azides. The carrier of this absorption also decayed bi‐exponentially, and the time constants were in excellent agreement with those found in the fs TRIR experiments. The slow component of the S1 state decay was found to be dependent on the solvent polarity. When the lifetime of the acyl azide S1 state is substantially longer than the time constant for vibrational cooling of nascent (hot) isocyanate, the correlation between the S1 decay and isocyanate formation was clear. The 270 nm excitation populates the Sn (n ≥ 2) states of these acyl azides. It was established that a hot nitrene is produced more efficiently from both the Sn and hot S1 states than from the relaxed S1 state of these acyl azides. Thus, time‐resolved study provides direct experimental evidence that the S1 state is the precursor of nitrene only when the S1 state is pumped directly and when the S1 state lifetime is longer than the time constant of vibrational cooling of the newborn nitrene. All of these results are consistent with the data obtained recently for 2‐napththoyl azide. Copyright © 2012 John Wiley & Sons, Ltd.

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“…1 Upon either heat or irradiation, this class of energetic compounds can split off molecular nitrogen and form highly reactive nitrene intermediates. 2 The decomposition of covalent azides, in particular carbonyl, 3 phosphoryl, 4 and sulfonyl azides 5 have attracted enormous theoretical and experimental interest since the discovery of the Curtiusrearrangement from carbonyl azides to isocyanates as early as 1890. 6 Generally, a stepwise decomposition via α-oxonitrenes, RC(O)N, R 2 P(O)N, and RS(O) 2 N is energetically more favorable than the concerted pathway, and these α-oxonitrenes in their singlet state coexist with an oxazirine-like resonance structure due to intramolecular N-O stabilizing interaction.…”

mentioning

confidence: 99%

“…6 Generally, a stepwise decomposition via α-oxonitrenes, RC(O)N, R 2 P(O)N, and RS(O) 2 N is energetically more favorable than the concerted pathway, and these α-oxonitrenes in their singlet state coexist with an oxazirine-like resonance structure due to intramolecular N-O stabilizing interaction. [3][4][5] However, due to complex reactions with solvents and Curtius rearrangement, only very few transient α-oxonitrenes have been detected using ultra-fast spectroscopy [3][4][5] and matrix isolation techniques. 7 Importantly, decomposition of α-oxoazides has provided unique access to N,O-containing species bearing novel structural and bonding properties such as N 2 CO, 8 OPN, 9 and O 2 SN, 10 in which the corresponding α-oxonitrenes were suggested to be involved.…”

mentioning

confidence: 99%

A Singlet Thiophosphoryl Nitrene and Its Interconversion with Thiazyl and Thionitroso Isomers

et al. 2015

J. Am. Chem. Soc.

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Thiophosphoryl nitrenes, R2P(S)N, are thiazirine-like intermediates that have been chemically inferred from trapping products in early solution studies. In this work, photolysis of the simplest thiophosphoryl azide, F2P(S)N3, in solid noble-gas matrices enabled a first-time spectroscopic (IR and UV-vis) identification of the thiophosphoryl nitrene F2P(S)N in its singlet ground state. Upon visible-light irradiation (≥495 nm), it converts into the thionitroso isomer F2P-N═S, which can also be produced in the gas phase from flash vacuum pyrolysis of F2P(S)N3. Further irradiation of F2P-NS with 365 nm UV light leads to the reformation of F2P(S)N and isomerization to the thiazyl species F2P-S≡N.

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Photochemistry of 2-Naphthoyl Azide. An Ultrafast Time-Resolved UV–Vis and IR Spectroscopic and Computational Study

Cited by 52 publications

References 49 publications

Photolysis of 3,5‐diphenylisoxazole in argon matrices

Photolysis of 3,5‐diphenylisoxazole in argon matrices

An ultrafast time‐resolved infrared and UV–vis spectroscopic and computational study of the photochemistry of acyl azides

A Singlet Thiophosphoryl Nitrene and Its Interconversion with Thiazyl and Thionitroso Isomers

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