This study addresses the anomalous fluorescence of a rhodanine-based organic dye of interest for nonlinear optical applications. At room temperature, the dye exhibits weak fluorescence, while spectra collected in glassy 2Me-THF at 77 K show a surprising fluorescence intensity increase by several orders of magnitude with respect to room temperature. Moreover, a pronounced dependence of the fluorescence quantum yield on the excitation wavelength is observed, indicating a breakdown of Vavilov's rule, a corollary of Kasha's rule, which states that the fluorescence quantum yield is independent of the excitation energy. Quantum chemical calculations demonstrate the presence of a bright ππ* excited state that lies very close in energy to a dark nπ* state. The subtle interplay between these two excited states with different natures is responsible for the intriguing spectral behavior of the dye. Specifically, experimental results are rationalized in terms of a population branching between the two excited states, which can be tuned upon varying the temperature or the excitation energy.
Racchi, O., Scurti, S., Liotino, S., Lanfranchi, A., Painelli, A., Comoretto, D., et al. (2026). Freezing Out Vavilov's Rule: Temperature‐Dependent Fluorescence of a Rhodanine Dye. CHEMPHOTOCHEM, 10(2), 1-9 [10.1002/cptc.202500255].
Freezing Out Vavilov's Rule: Temperature‐Dependent Fluorescence of a Rhodanine Dye
Scurti, Stefano;Caretti, Daniele;
2026
Abstract
This study addresses the anomalous fluorescence of a rhodanine-based organic dye of interest for nonlinear optical applications. At room temperature, the dye exhibits weak fluorescence, while spectra collected in glassy 2Me-THF at 77 K show a surprising fluorescence intensity increase by several orders of magnitude with respect to room temperature. Moreover, a pronounced dependence of the fluorescence quantum yield on the excitation wavelength is observed, indicating a breakdown of Vavilov's rule, a corollary of Kasha's rule, which states that the fluorescence quantum yield is independent of the excitation energy. Quantum chemical calculations demonstrate the presence of a bright ππ* excited state that lies very close in energy to a dark nπ* state. The subtle interplay between these two excited states with different natures is responsible for the intriguing spectral behavior of the dye. Specifically, experimental results are rationalized in terms of a population branching between the two excited states, which can be tuned upon varying the temperature or the excitation energy.| File | Dimensione | Formato | |
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ChemPhotoChem - 2026 - Racchi - Freezing Out Vavilov s Rule Temperature‐Dependent Fluorescence of a Rhodanine Dye.pdf
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