2024
DOI: 10.1021/jacs.4c01165
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High Quantum Yields from Perfluorinated Binolate Erbium Complexes and Their Circularly Polarized Luminescence

Joseph A. Adewuyi,
Gaël Ung

Abstract: High quantum yield and circularly polarized luminescence (CPL) brightness values are reported from Shibasaki-type erbium complexes supported by a perfluorinated Binol ligand (F12Binol). The total fluorination of the ligand circumvents nonradiative quenching from Csp2-H vibrations and leads to quantum yields of up to 11% and CPL brightness values of up to 317 M–1 cm–1 (a 19- and 6-fold increase, respectively, compared to (Binol)3ErNa3). These values are the highest values for any molecular erbium complex to dat… Show more

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Cited by 12 publications
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“…Leading NIR II-emitting lumiphores rely on complex scaffolds with large, conjugated motifs to shift absorption and emission energies into this low-energy region; ,, however, these complex scaffolds prevent facile synthetic tuning of photophysical properties. Scaffolds with tunable NIR absorption/emission would be valuable as they would also allow for targeted and multicolor imaging. , Furthermore, multicolor imaging can additionally be enhanced and leveraged with dyes that are responsive to various environments; this approach can give additional environmental information as a result of emission or absorption shifts. In addition to NIR II bioimaging, complexes that emit in the low attenuation telecom bands (∼1260–1550 nm) are of special interest for communication-related applications. , In particular, open-shell complexes that emit in this region would be ideal candidates for sensing and transmitting quantum information.…”
Section: Introductionmentioning
confidence: 99%
“…Leading NIR II-emitting lumiphores rely on complex scaffolds with large, conjugated motifs to shift absorption and emission energies into this low-energy region; ,, however, these complex scaffolds prevent facile synthetic tuning of photophysical properties. Scaffolds with tunable NIR absorption/emission would be valuable as they would also allow for targeted and multicolor imaging. , Furthermore, multicolor imaging can additionally be enhanced and leveraged with dyes that are responsive to various environments; this approach can give additional environmental information as a result of emission or absorption shifts. In addition to NIR II bioimaging, complexes that emit in the low attenuation telecom bands (∼1260–1550 nm) are of special interest for communication-related applications. , In particular, open-shell complexes that emit in this region would be ideal candidates for sensing and transmitting quantum information.…”
Section: Introductionmentioning
confidence: 99%