Sensitive and selective ratiometric nanosensors for visual detection of Cu2+ based on ions promoted oxidation reaction

- A novel hybrid ratiometric fluorescent nanosensor has been developed.
- The nanosensor can detect Cu2+ sensitively due to ion promoted oxidation mechanism.
- The detection limit of the nanosensor towards Cu2+ is 41.71 nM.
- The nanosensor shows high performance for Cu2+ detection in actual water samples.

Copper is a highly toxic environmental pollutant in the environmental, biological and chemical fields. Therefore, sensitive, selective and visual detection of Cu2+ is very important for human health and practical applications. Herein, a novel hybrid ratiometric fluorescent nanosensor was developed for rapid and on-site visualization of Cu2+ on the basis of integrating benzothiazole fluorophore (MDBT) and red-emissive quantum dots (QDs) embedded in silica nanospheres. Such hybrid ratiometric fluorescent nanosensor exhibits dual emissions at 420 and 640 nm under a single excitation wavelength. Due to the ions promoted oxidation reaction of Cu2+ towards MDBT, the fluorescence of MDBT can be selectively enhanced. Although the embedded QDs are insensitive to the analyte, variations of the dual emission intensity ratios display continuous colour changes from red to blue. The ratiometric fluorescent approach shows high sensitivity and selectivity towards Cu2+ against other interfering metal ions. The detection limit of Cu2+ for the hybrid ratiometric fluorescent nanosensor is determined to be 41.71 nM, which is much lower than the allowable level of Cu2+ (∼20 μM) in drinking water set by U.S. Environmental Protection Agency. Furthermore, this kind of novel nanosensor can also be applied for Cu2+ detection in actual water samples and exhibits excellent detection ability. This hybrid ratiometric fluorescent nanosensor is simple, fully self-contained and thus potentially attractive for visual identification without the need of elaborate equipments.

A novel hybrid ratiometric fluorescent nanosensor was developed for rapid and on-site visualization of Cu2+ based on the ions promoted catalytic oxidation mechanism.96