Microemulsions (MEs) comprising of cholinium dodecylbenzene sulphonate Cho[DBS], a bio-based ionic liquid surfactant as an emulsifier, hydrophobic deep eutectic solvent (HDES) as nonpolar phase, and water as a polar component are constructed. Negative value of triangle G estimated from isothermal titration calorimetry (ITC) plots indicate spontaneous aggregation of Cho[DBS] both in water and HDES. The aggregates of Cho[DBS] in HDES and water show the critical micellar concentration (cmc) of approximate to 4.26 and approximate to 2.4 mMm, respectively. Cho[DBS] shows a better emulsifying capacity with a high monophasic region in the ternary phase diagram. MEs are utilized as nanoreactors for the sustainable synthesis of nano-sized fluorescent carbon nanoparticles (FCNPs) with precise control over size and morphology. FCNPs are characterized using PXRD, Raman, XPS, HR-TEM, UV-vis, and Fluorescence spectroscopic techniques. FCNPs exhibited remarkable properties viz. adjustable luminescence, good solubility, and biocompatibility. FCNPs are applied for fluorometric sensing of nitroaromatic compounds (NACs) and antibiotics through a quenching response originating from the inner filter effect, with a fast response nanomolar detection, and are found highly selective toward TNP (NAC), NFT, and NZF (antibiotics). This work introduces neoteric solvent-based microemulsions (MEs) as an innovative method for synthesizing fluorescent carbon nanoparticles (FCNPs). The results indicate that MEs provide good control over size of FCNPs in the nanometer range. FCNPs exhibit excellent photo-optical properties and are subsequently used for sensing antibiotics and nitroaromatic compounds in the nanomolar range with high sensitivity. image
