Continuous and precise recognition of N2H4 and Cu2+ has been achieved using chalcone derivatives as a D-A-D΄-type fluorescent chemical sensor

Abstract

A fluorescent probe, FZ, based on the ESIPT and ICT mechanisms was designed. It transformed from a ratio probe to a fluorescence turn-on probe using the properties of the ICT mechanism, enhancing the sensitivity for detecting N2H4. The calculated detection limit was 3.39 × 10-8 M. The existence of intramolecular hydrogen bonds between O–H and C = O was confirmed through single crystal structure analysis. Additionally, taking advantage of the structural features of FZN generated from the reaction of FZ with N2H4, it was developed into a new quenching-type Cu2+ fluorescent probe with a detection limit of 1.47 × 10-8 M, achieving high sensitivity and selectivity for Cu2+ detection. Furthermore, it was adapted into a fluorescence TLC testing plate for detecting trace amounts of Cu2+ in the environment, demonstrating its potential applicability in Cu2+ detection.