Bichromophoric Photosensitizers: How and Where to Attach Pyrene Moieties to Phenanthroline to Generate Copper(I) Complexes

Doettinger, Florian; Yang, Yingya; Karnahl, Michael; Tschierlei, Stefanie

doi:10.1021/acs.inorgchem.3c00482

Cited by 9 publications

(3 citation statements)

References 119 publications

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“…5,9 In this context, the significance of copper complexes should be noted due to their participation in vital biological functions and relatively modest toxicity in comparison to other heavy metals. [16][17][18] Moreover, these complexes exhibit anticancer properties attributed to their photo-redox activity, enabling them to produce cytotoxic reactive oxygen species (ROS). 19 Although the primary responsibility of incorporating free Cu(II) ions into cells lies with the copper transporter hCTR1, it is passive diffusion that predominantly accounts for the absorption of Cu(II) complexes.…”

Section: Introductionmentioning

confidence: 99%

Cu(ii) flavonoids as potential photochemotherapeutic agents

Das,

Bora,

Upadhyay

et al. 2024

Dalton Trans.

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Section: Introductionmentioning

confidence: 99%

Cu(ii) flavonoids as potential photochemotherapeutic agents

Das,

Bora,

Upadhyay

et al. 2024

Dalton Trans.

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“…Two classes of Cu(I) bis -phenanthrolines engender either homoleptic or heteroleptic ligand topologies. Homoleptic cuprous phenanthrolines have been studied since the 1970s for their potent photoreducing capabilities, long-lived excited states, and tremendous durability to high-power laser excitation. ,,− Heteroleptic complexes using diimine- and bis -phosphine-type ligands have been growing in interest, especially for applications in dye-sensitized solar cells, − photoredox catalysis, − and the construction of supramolecular donor–acceptor architectures. ,,− The HETPHEN strategy leverages 2,9-mesityl-1,10-phenanthroline (mesPhen), ,, which is unable to form a bis -homoleptic complex but enables the binding of another suitable phenanthroline, assisted through π-interactions with the 2,9-mesityl substituents and the B-ring of the orthogonally coordinated phenanthroline. This platform facilitates a facile pathway for obtaining heteroleptic Cu(I) complexes with the generic formula [Cu(mesPhen)(L)] + , where L is a second and distinct phenanthroline ligand (Chart ).…”

Section: Introductionmentioning

confidence: 99%

Enhanced Visible Light Absorption in Heteroleptic Cuprous Phenanthrolines

Rosko,

Wheeler,

Alameh

et al. 2024

Inorg. Chem.

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This work presents a series of Cu(I) heteroleptic 1,10-phenanthroline chromophores featuring enhanced UVA and visible-light-harvesting properties manifested through vectorial control of the copper-to-phenanthroline chargetransfer transitions. The molecules were prepared using the HETPHEN strategy, wherein a sterically congested 2,9-dimesityl-1,10-phenanthrolne (mesPhen) ligand was paired with a second phenanthroline ligand incorporating extended π-systems in their 4,7-positions. The combination of electrochemistry, static and timeresolved electronic spectroscopy, 77 K photoluminescence spectra, and timedependent density functional theory calculations corroborated all of the experimental findings. The model chromophore, [Cu(mesPhen)(phen)] + (1), lacking 4,7-substitutions preferentially reduces the mesPhen ligand in the lowest energy metal-to-ligand charge-transfer (MLCT) excited state. The remaining cuprous phenanthrolines (2−4) preferentially reduce their π-conjugated ligands in the low-lying MLCT excited state. The absorption cross sections of 2−4 were enhanced (ε MLCTmax = 7430−9980 M −1 cm −1 ) and significantly broadened across the UVA and visible regions of the spectrum compared to 1 (ε MLCTmax = 6494 M −1 cm −1 ). The excited-state decay mechanism mirrored those of long-lived homoleptic Cu(I) phenanthrolines, yielding three distinguishable time constants in ultrafast transient absorption experiments. These represent pseudo-Jahn−Teller distortion (τ 1 ), singlet−triplet intersystem crossing (τ 2 ), and the relaxed MLCT excited-state lifetime (τ 3 ). Effective light-harvesting from Cu(I)-based chromophores can now be rationalized within the HETPHEN strategy while achieving directionality in their respective MLCT transitions, valuable for integration into more complex donor− acceptor architectures and longer-lived photosensitizers.

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“…One means by which this can be achieved is through the incorporation of large aromatic chromophores. This can facilitate a population of triplet ligand-centered ( 3 LC) states, which typically have much longer lifetimes than their triplet metal-to-ligand charge-transfer ( 3 MLCT) state counterparts due to their localization away from the metal center. ,,− For example, a recent study by Choroba et al investigated pyrene-substituted Re(I) complexes with room-temperature phosphorescent lifetimes greater than 1000 μs . Similarly, a study by Wenger and co-workers showed that naphthalene was able to function as a triplet reservoir in an Ir(III) complex, leading to lifetimes of 72.1 μs .…”

Section: Introductionmentioning

confidence: 99%

Controlling Excited State Localization in Bichromophoric Photosensitizers via the Bridging Group

Shillito,

Preston,

Crowley

et al. 2024

Inorg. Chem.

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A series of photosensitizers comprised of both an inorganic and an organic chromophore are investigated in a joint synthetic, spectroscopic, and theoretical study. This bichromophoric design strategy provides a means by which to significantly increase the excited state lifetime by isolating the excited state away from the metal center following intersystem crossing. A variable bridging group is incorporated between the donor and acceptor units of the organic chromophore, and its influence on the excited state properties is explored. The Franck−Condon (FC) photophysics and subsequent excited state relaxation pathways are investigated with a suite of steady-state and time-resolved spectroscopic techniques in combination with scalar-relativistic quantum chemical calculations. It is demonstrated that the presence of an electronically conducting bridge that facilitates donor−acceptor communication is vital to generate long-lived (32 to 45 μs), charge-separated states with organic character. In contrast, when an insulating 1,2,3-triazole bridge is used, the excited state properties are dominated by the inorganic chromophore, with a notably shorter lifetime of 60 ns. This method of extending the lifetime of a molecular photosensitizer is, therefore, of interest for a range of molecular electronic devices and photophysical applications.

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Bichromophoric Photosensitizers: How and Where to Attach Pyrene Moieties to Phenanthroline to Generate Copper(I) Complexes

Cited by 9 publications

References 119 publications

Cu(ii) flavonoids as potential photochemotherapeutic agents

Cu(ii) flavonoids as potential photochemotherapeutic agents

Enhanced Visible Light Absorption in Heteroleptic Cuprous Phenanthrolines

Controlling Excited State Localization in Bichromophoric Photosensitizers via the Bridging Group

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