Development of probe technology by quantum overlap for controlling spectroscopic behaviors in organic dyes

Quantitative interference and its benefits on organic dye energy levels were examined in this study. The dye combined with the material had an absorption coefficient of 0.285 at 657 nm, according to UV–visible spectroscopy. From the results obtained, we observed a clear difference in the intensity of the absorption spectrum, which indicates that the energy levels of the dye have short absorption times. We also observed a decrease in the FWHM value, which indicates that the dye possesses a specific and sharp absorption effect. Rhodamine 6G was chosen as the optical material for its ability to be used to produce optical filters by controlling the inverse distribution between energy levels, allowing adjustments to be made immediately. The energy gap is greatly improved due to the use of Cu nanomaterials, as they cause a decrease in the free path and an increase in reflections, resulting in an increase in the absorption cross section. This optimization contributes to improved absorption efficiency and increased visual outcomes. Rhodamine 6G dye and copper nanoparticles were used in the experiment to study how quantum interference affects light absorption of an organic dye. The goal was to improve how well the dye absorbs light and get better optical results. The study came to the conclusion that quantum interference and improvements to nanostructures can be used to improve the energy levels and absorption efficiency of organic dyes. This will help to develop more advanced photonic applications in the future and make optical technology more useful.