Alexis TigrerosSandra‐L. AranzazuNéstor-F. BravoJhon Zapata‐RiveraJaime Portilla2026-03-222026-03-22202010.1039/d0ra07716jhttps://doi.org/10.1039/d0ra07716jhttps://andeanlibrary.org/handle/123456789/43648Citaciones: 54Fluorescent molecules are crucial tools for studying the dynamics of intracellular processes, chemosensors, and the progress of organic materials. In this study, a family of pyrazolo[1,5-<i>a</i>]pyrimidines (PPs) 4a-g has been identified as strategic compounds for optical applications due to several key characteristics such as their simpler and greener synthetic methodology (RME: 40-53%) as compared to those of BODIPYS (RME: 1.31-17.9%), and their tunable photophysical properties (going from <i>ε</i> = 3320 M^-1 cm^-1 and <i>ϕ</i> _F = 0.01 to <i>ε</i> = 20 593 M^-1 cm^-1 and <i>ϕ</i> _F = 0.97), in which electron-donating groups (EDGs) at position 7 on the fused ring improve both the absorption and emission behaviors. The PPs bearing simple aryl groups such as 4a (4-Py), 4b (2,4-Cl₂Ph), 4d (Ph) and 4e (4-MeOPh), allow good solid-state emission intensities (QY_SS = 0.18 to 0.63) in these compounds and thus, solid-state emitters can be designed by proper structural selection. The properties and stability found in 4a-g are comparable to commercial probes such as coumarin-153, prodan and rhodamine 6G. Ultimately, the electronic structure analysis based on DFT and TD-DFT calculations revealed that EDGs at position 7 on the fused ring favor large absorption/emission intensities as a result of the ICT to/from this ring; however, these intensities remain low with electron-withdrawing groups (EWGs), which is in line with the experimental data and allows us to understand the optical properties of this fluorophore family.enChemistryComputational chemistryNanotechnologyarticle