Thermally-assisted photosensitized emission in a trivalent terbium complex

Kitagawa, Yuichi; Shima, Kaori; Nakai, Takuma; Kumagai, Marina; Omagari, Shun; Rosa, Pedro Paulo Ferreira da; Shoji, Sunao; Fushimi, Koji; Hasegawa, Yasuchika

doi:10.1038/s42004-023-00922-5

Cited by 6 publications

(6 citation statements)

References 43 publications

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“…Alternatively, measurements of the T 1 lifetimes might provide further valuable information. , A longer lifetime (>1 ms) allows sufficient time for populating the T 1 state and transferring energy to the Ln III ions. On the other hand, a shorter lifetime (in the order of microseconds) indicates a weak population of this level.…”

Section: Results and Discussionmentioning

confidence: 99%

Tuning the Emission of Homometallic Dy^III, Tb^III, and Eu^III 1-D Coordination Polymers with 2,6-Di(1H-1,2,4-triazole-1-yl-methyl)-4-R-phenoxo Ligands: Sensitization through the Singlet State

Manzur,

Fuentealba,

Gil

et al. 2023

Inorg. Chem.

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This work reports the structural characterization and photophysical properties of DyIII, TbIII, and EuIII coordination polymers with two phenoxo-triazole-based ligands [2,6-di(1H-1,2,4-triazole-1-yl-methyl)-4-R-phenoxo, LRTr (R = CH3; Cl)]. These ligands permitted us to obtain isostructural polymers, described as a 1D double chain, with LnIII being nona-coordinated. The energies of the ligand triplet (T1) states were estimated using low-temperature time-resolved emission spectra of YIII analogues. Compounds with LClTr present higher emission intensity than those with LMeTr. The emission of TbIII compounds was not affected by the different excitation wavelengths used and was emitted in the pure green region. In contrast, DyL Me Tr emits in the blue-to-white region, while the luminescence of DyL Cl Tr remains in the white region for all excitation wavelengths. On the other hand, EuIII compounds emit in the blue (ligand) or red region (EuIII) depending on the substituent of the phenoxo moiety and excitation wavelength. Theoretical calculations were employed to determine the excited states of the ligands by using time-dependent density functional theory. These calculations aided in modeling the intramolecular energy transfer and rationalizing the optical properties and demonstrated that the sensitization of the LnIII ions is driven via S1 → LnIII, a process that is less common as compared to T1 → LnIII.

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Section: Results and Discussionmentioning

confidence: 99%

Tuning the Emission of Homometallic Dy^III, Tb^III, and Eu^III 1-D Coordination Polymers with 2,6-Di(1H-1,2,4-triazole-1-yl-methyl)-4-R-phenoxo Ligands: Sensitization through the Singlet State

Manzur,

Fuentealba,

Gil

et al. 2023

Inorg. Chem.

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“…Therefore, the long-lasting T 1 excited state promotes efficient T 1 !Ln* energy transfer and enables efficient population of Ln(III) emitting states, even if the energy of T 1 excited state of ligand is equivalent to or lower than that of Ln* state (which cause back energy transfer (BEnT), Figure 2b). [45][46][47] On the other hand, the evaluation of the energy transfer process T 1 !Ln* can be represented as sensitization efficiency (η sens ) described in equation (1). The 4 f-4 f transition including radiative rate (k r ) and nonradiative rate (k nr ) constants are expressed in equation ( 2).…”

Section: Photosensitized Luminescence Propertiesmentioning

confidence: 99%

“…Therefore, the long–lasting T 1 excited state promotes efficient T 1 →Ln* energy transfer and enables efficient population of Ln(III) emitting states, even if the energy of T 1 excited state of ligand is equivalent to or lower than that of Ln* state (which cause back energy transfer (BEnT), Figure 2b). [45–47] …”

Section: Photosensitized Luminescence Propertiesmentioning

confidence: 99%

Current Development of Lanthanide Complexes for Biomedical Applications

Wang,

Kitagawa,

Hasegawa

2024

Chemistry An Asian Journal

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Luminescent molecule‐based bioimaging system is widely used for precise localization and distinction of cancer/tumor cells. Luminescent lanthanide (Ln(III)) complexes offer long‐lived (sub‐millisecond time scale) and sharp (FWHM <10nm) emission, arising from the forbidden 4f‐4f electronic transitions. Luminescent Ln(III) complex‐based bioimaging has emerged as a promising option for both in vitro and in vivo visualizations. In this mini‐review, the historical development and recent significant progress of luminescent Ln(III) probes for bioapplications are introduced. The recent studies are mainly focused on three points: (i) the structural modifications of Ln(III) complexes in both macrocyclic and small ligands, (ii) the acquirement of high resolution luminescence images of cancer/tumor cells and (iii) the constructions of ratiometric biosensors. Furthermore, our recent study is explained as a new cancer GPS (growth positioning system) for determining tumor grade through photophysical property analyses of intracellular Eu(III) complex.

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“…24 The photosensitization model with a low T 1 level is beneficial for enhancing the brightness of Tb( iii ) emission (ESI in ref. 25). 25 However, the emission intensity of the Tb( iii ) luminophores is diminished by triplet oxygen quenching when using long-lived T 1 photosensitizers.…”

Section: Introductionmentioning

confidence: 99%

“…25). 25 However, the emission intensity of the Tb( iii ) luminophores is diminished by triplet oxygen quenching when using long-lived T 1 photosensitizers. 10,26–31…”

Section: Introductionmentioning

confidence: 99%

Effective photosensitized emission of a Tb(iii) complex using a β-diketonate photosensitizer and an oxygen barrier system in a thermally populated triplet state

Inage,

Wang,

Hasegawa

et al. 2024

Dalton Trans.

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Thermally-assisted photosensitized emission in a trivalent terbium complex

Cited by 6 publications

References 43 publications

Tuning the Emission of Homometallic Dy^III, Tb^III, and Eu^III 1-D Coordination Polymers with 2,6-Di(1H-1,2,4-triazole-1-yl-methyl)-4-R-phenoxo Ligands: Sensitization through the Singlet State

Tuning the Emission of Homometallic Dy^III, Tb^III, and Eu^III 1-D Coordination Polymers with 2,6-Di(1H-1,2,4-triazole-1-yl-methyl)-4-R-phenoxo Ligands: Sensitization through the Singlet State

Current Development of Lanthanide Complexes for Biomedical Applications

Effective photosensitized emission of a Tb(iii) complex using a β-diketonate photosensitizer and an oxygen barrier system in a thermally populated triplet state

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Thermally-assisted photosensitized emission in a trivalent terbium complex

Cited by 6 publications

References 43 publications

Tuning the Emission of Homometallic DyIII, TbIII, and EuIII 1-D Coordination Polymers with 2,6-Di(1H-1,2,4-triazole-1-yl-methyl)-4-R-phenoxo Ligands: Sensitization through the Singlet State

Tuning the Emission of Homometallic DyIII, TbIII, and EuIII 1-D Coordination Polymers with 2,6-Di(1H-1,2,4-triazole-1-yl-methyl)-4-R-phenoxo Ligands: Sensitization through the Singlet State

Current Development of Lanthanide Complexes for Biomedical Applications

Effective photosensitized emission of a Tb(iii) complex using a β-diketonate photosensitizer and an oxygen barrier system in a thermally populated triplet state

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Tuning the Emission of Homometallic Dy^III, Tb^III, and Eu^III 1-D Coordination Polymers with 2,6-Di(1H-1,2,4-triazole-1-yl-methyl)-4-R-phenoxo Ligands: Sensitization through the Singlet State

Tuning the Emission of Homometallic Dy^III, Tb^III, and Eu^III 1-D Coordination Polymers with 2,6-Di(1H-1,2,4-triazole-1-yl-methyl)-4-R-phenoxo Ligands: Sensitization through the Singlet State