Exchange Interaction in Radical−Triplet Pairs:  Evidences for CIDEP Generation by Level Crossings in Triplet−Doublet Interactions

Kobori, Yasuhiro; Takeda, K.; Tsuji, Kentaro; Kawai, and Akio; Obi, Kinichi

doi:10.1021/jp980870r

Cited by 78 publications

(118 citation statements)

References 39 publications

(158 reference statements)

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“…Actually, the magnitude of the exchange coupling between the photoexcited triplet state and radical spin in the weak exchangecoupled spin systems were determined using time-resolved ESR (TRESR) spectroscopy. 6 When the target system is emissive, the magnitude of the stronger spin-exchange coupling in the photoexcited-tripletdoublet coupled spin systems can be also determined by the temperature dependence of the emission intensity as demonstrated for a fluorescent metal-complex radical hybrid; 7 the lifetime of the spin polarization in this hybrid was also temperature-dependent, as obtained for the emission lifetime. In our previous papers, 8 we reported the first observation of a quartet (S = 3/2) photoexcited state and a quintet (S = 2) photoexcited state in organic π-radicals that were generated by a robust spin alignment through π-conjugation between stable iminonitroxide radicals (S = 1/2) and the triplet (S = 1) excited state of a phenyl-or diphenylanthracene derivative, which are ideal model systems in order to study the relationship between the π-topology and photoinduced spin alignment.…”

mentioning

confidence: 97%

Excited-state Dynamics and Spin-exchange Coupling of Anthracene–Verdazyl Radical in Frozen Glass Matrix Investigated by Transient Absorption Spectroscopy

Ito¹,

Hinoshita²,

Kato³

et al. 2016

Chem. Lett.

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Excited-state dynamics of an anthraceneverdazyl radical diluted in a frozen glass matrix (2-MTHF) has been clarified by transient absorption spectroscopy. The magnitude of the intramolecular exchange coupling was determined from the temperature dependence of the decay time of the transient absorption signal of the high-spin quartet state, which was consistent with the theoretical prediction. since a large negative magneto-resistance of organic radical system was demonstrated by Sugawara et al. 3 Intra-or intermolecular spin alignment and exchange interaction through π-conjugation or π-orbital packing in purely organic spin systems play key roles in their research fields. However, most of these studies are limited to ground-state systems. 4 The studies of the exchange interaction between the triplet excited state and radical spin(s) will give very important knowledge on the forthcoming excited-state organic spintronics and photocontrol of the magnetic properties. 5 This knowledge leads to a new strategy for the photoinduced/switching magnetic spin systems, the photocontrol of the molecule-based magnetism and future organic spintronics devices using photoexcitation. Only for very weak exchange coupling, ESR spectroscopy gives direct information on the magnitude of the exchange coupling. Actually, the magnitude of the exchange coupling between the photoexcited triplet state and radical spin in the weak exchangecoupled spin systems were determined using time-resolved ESR (TRESR) spectroscopy.6 When the target system is emissive, the magnitude of the stronger spin-exchange coupling in the photoexcited-tripletdoublet coupled spin systems can be also determined by the temperature dependence of the emission intensity as demonstrated for a fluorescent metal-complex radical hybrid; 7 the lifetime of the spin polarization in this hybrid was also temperature-dependent, as obtained for the emission lifetime. In our previous papers, 8 we reported the first observation of a quartet (S = 3/2) photoexcited state and a quintet (S = 2) photoexcited state in organic π-radicals that were generated by a robust spin alignment through π-conjugation between stable iminonitroxide radicals (S = 1/2) and the triplet (S = 1) excited state of a phenyl-or diphenylanthracene derivative, which are ideal model systems in order to study the relationship between the π-topology and photoinduced spin alignment. We demonstrated that the spin multiplicities of the photoexcited state observed by the TRESR were dependent on the π-topology.8b,9 We have also investigated π-conjugated spin systems constructed from other polycyclic aromatic hydrocarbons (pyrene or pentacene) and covalently-linked stable radicals. 10,11 The magnitude of the intramolecular exchange coupling of their π-radical spin systems was, however, estimated only from theoretical calculations, 12 because the magnitude was much larger than that accessible by ESR spectroscopy and highspin photoexcited state was almost non-emissive (very weak phosphorescent).

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mentioning

confidence: 97%

Excited-state Dynamics and Spin-exchange Coupling of Anthracene–Verdazyl Radical in Frozen Glass Matrix Investigated by Transient Absorption Spectroscopy

Ito¹,

Hinoshita²,

Kato³

et al. 2016

Chem. Lett.

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“…The spin polarization lifetimes of both nitroxides 2-14 N and 3 are the same within experimental error (3.9 and 3.8 µs, respectively), and are in agreement with reported values of TEMPO spin polarization lifetimes in solution. 1,29 To study the benzophenone triplet quenching kinetics by nitroxides inside the zeolites in more detail, diffuse reflectance laser flash photolysis was performed. Laser flash photolysis (308 nm, 10 ns) of 1 loaded on NaY affords a readily detectable transient absorption at 525 nm corresponding to the triplet state of 1 (Figure 5a).…”

Section: Resultsmentioning

confidence: 99%

Time Resolved CW-EPR Spectroscopy of Powdered Samples: Electron Spin Polarization of a Nitroxyl Radical Adsorbed on NaY Zeolite, Generated by the Quenching of Excited Triplet Ketones

et al. 2001

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Chemically induced dynamic electron polarization (CIDEP) generated in a faujasite zeolite (NaY) by the interaction between a stable free radical (4-oxo-TEMPO) and the triplet state of benzophenone was investigated by time-resolved electron spin resonance spectroscopy (TR-CW-EPR). The TR-CW-EPRs were performed by either pulling a long tube containing powdered zeolite through the EPR cavity during the laser irradiation, or by flowing a liquid transport medium (polydimethylsiloxane) for the zeolite powder, through a flat cell in the EPR cavity. CIDEP was observed for intermolecular triplet quenching (benzophenone triplets with 4-oxo-TEMPO) and intramolecular triplet quenching using a covalently linked TEMPO-benzophenone molecule. The identification of the polarized nitroxide structure was confirmed by employing both 14 N and 15 N 4-oxo-TEMPO isotopomers. The kinetics of the triplet quenching inside the zeolite were studied by diffuse reflection laser flash photolysis.

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“…Following the widespread use of lasers in EPR experiments, there have been some new observations of CIDEP of stable radicals in solution in the presence of photoexcited triplet chromophores. This polarization could not be explained by the above mechanisms and was treated theoretically [29][30][31][32][33][34] by the RTPM and ESPT, which are the main themes of this part of the paper.…”

Section: Radical-photoinduced Triplet Interaction the Radical-tripletmentioning

confidence: 99%

“…Current theories provide analytical [29,[35][36][37] and numerical [34] results for the dependence of the spin polarization upon the zero-field splitting (ZFS) parameter (D), solvent viscosity (Z) and radical-triplet electron spin exchange (J). According to RTPM theory, the observed net polarization, which is equal for all hyperfine lines, depends on the precursor state (photoexcited singlet or triplet) and sign of J [38][39][40][41].…”

Section: Radical-photoinduced Triplet Interaction the Radical-tripletmentioning

confidence: 99%

Triplet porphyrins as donors in intramolecular electron transfer and their intermolecular interaction with free radicals

Blank

Galili

Levanon

2001

J. Porphyrins Phthalocyanines

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Porphyrins and related compounds are basic moieties which upon photoexcitation produce paramagnetic transients important to many processes in biology, material science and light–energy conversion. This short review demonstrates the application of time-resolved EPR spectroscopy to two processes in which the photoexcited singlet and/or triplet are involved: (1) intramolecular electron transfer in photoexcited donor–acceptor systems embedded in liquid crystals, where the porphyrins are the electron donors attached to different types of acceptors; and (2) intermolecular magnetic interactions between photoexcited porphyrin triplets and free radicals. In both systems the electron spin plays an important part with regards to the route of the magnetic interactions involved.

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Exchange Interaction in Radical−Triplet Pairs: Evidences for CIDEP Generation by Level Crossings in Triplet−Doublet Interactions

Cited by 78 publications

References 39 publications

Excited-state Dynamics and Spin-exchange Coupling of Anthracene–Verdazyl Radical in Frozen Glass Matrix Investigated by Transient Absorption Spectroscopy

Excited-state Dynamics and Spin-exchange Coupling of Anthracene–Verdazyl Radical in Frozen Glass Matrix Investigated by Transient Absorption Spectroscopy

Time Resolved CW-EPR Spectroscopy of Powdered Samples: Electron Spin Polarization of a Nitroxyl Radical Adsorbed on NaY Zeolite, Generated by the Quenching of Excited Triplet Ketones

Triplet porphyrins as donors in intramolecular electron transfer and their intermolecular interaction with free radicals

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