Abstract
This study presents an extensive analysis of the predictive power of time-dependent density functional theory in determining the excited-state properties of two groups of important fluorescent dyes, difluoroboranes and hydroxyphenylimidazo[1,2-a]pyridine derivatives. To ensure statistically meaningful results, the data set is comprised of 85 molecules manifesting diverse photophysical properties. The vertical excitation energies and dipole moments (in the electronic ground and excited states) of the aforementioned dyes were determined using the RI-CC2 method (reference) and with 18 density functional approximations (DFA). The set encompasses DFAs with varying amounts of exact exchange energy (EEX): from 0% (e.g., SVWN, BLYP), through a medium (e.g., TPSSh, B3LYP), up to a major contribution of EEX (e.g., BMK, MN15). It also includes range-separated hybrids (CAM-B3LYP, LC-BLYP). Similar error profiles of vertical energy were obtained for both dye groups, although the errors related to hydroxyphenylimidazopiridines are significantly larger. Overall, functionals including 40–55% of EEX (SOGGA11-X, BMK, M06-2X) ensure satisfactory agreement with the reference vertical excitation energies obtained using the RI-CC2 method; however, MN15 significantly outperforms them, providing a mean absolute error of merely 0.04 eV together with a very high correlation coefficient ( = 0.98). Within the investigated set of functionals, there is no single functional that would equally accurately determine ground- and excited-state dipole moments of difluoroboranes and hydroxyphenylimidazopiridine derivatives. Depending on the chosen set of dyes, the most accurate predictions were delivered by MN15 incorporating a major EEX contribution (difluoroboranes) and by PBE0 containing a minor EEX fraction (hydroxyphenylimidazopiridines). Reverse trends are observed for , i.e., for difluoroboranes the best results were obtained with functionals including a minor fraction of EEX, specifically PBE0, while in the case of hydroxyphenylimidazopiridines, much more accurate predictions were provided by functionals incorporating a major EEX contribution (BMK, MN15).
Highlights
Unceasing development of various technologies entails an increasing demand for fluorescent dyes meeting strictly defined criteria
We present the results of the calculations performed for the lowest excitations of the isolated molecules, which were carried out to determine the density functional approximations (DFA) with the highest predictive power, for both the vertical energy and dipole moments
All structures of difluoroboranes included within this study were synthesized by the Osmiałowski group [165,166,167,168,169], while the HPIP set consists of structures reported by Acuña [170], Gryko [171,172,173,174], Cossio [175], Araki [176], Shimada [177] and Bajipali [178]
Summary
Unceasing development of various technologies entails an increasing demand for fluorescent dyes meeting strictly defined criteria. In the context of biomedical applications, the most valuable fluorescent dyes display absorption/emission bands shifted into the near-infrared range. Those so-called NIR dyes are used in numerous medical imaging techniques, such as FACS (Fluorescence-Activated Cell Sorting) [1,2,3], FLIM (Fluorescence-Lifetime Imaging Microscopy) [4,5,6], or FIGS (Fluorescence ImageGuided Surgery) [7,8,9]. Fluorescent dyes can be used in imaging techniques benefiting from the two-photon absorption phenomenon [6,10,11,12,13]. The effort of many research groups is directed towards designing fluorescent dyes for specific applications, e.g., for monitoring the biological functions of organs [16,17,18], the detection of ions in living organisms [19,20,21], or for the analysis of the causes of neurodegenerative diseases [22,23,24,25]
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