Dual-mode sensing strategy based on carbon dots for sensitive and selective detection of molybdate ions

Two kinds of carbon dots with the maximum fluorescence peak of 492 nm (named as G-CDs) and 607 nm (named as R-CDs) were synthesized. In the presence of MoO 4 2− ions, the fluorescence of R-CDs at 607 nm can be quenched, which can probably be assigned to their aggregation caused by MoO 4 2− , while that of G-CDs at 492 nm remained unchanged. For the first time, a ratiometric fluorescence probe was developed for MoO 4 2− ions detection. In the range 0.25 ~ 100 μM, the fluorescence ratio (F 492 /F 607 ) of the probe was linearly related to MoO 4 2− concentration, and the detection limit was 61.5 nM, which fully meets the minimum detection requirements of MoO 4 2− ions in drinking water. On the other hand, when MoO 4 2− was introduced, a significant fading phenomenon of R-CDs can be observed with the naked eye; thereby, the colorimetric method can also be proposed. Based on above, the ratiometric fluorometric/colorimetric dual-mode sensing method was established for MoO 4 2− anion quantification. Compared with the traditional analysis methods, the results obtained by multimodal sensing can be mutually verified, which effectively improves the accuracy and reliability. The dual-mode assay proposed in this work provides an alternative scheme to meet the need of sensing target compounds in complex matrices. Graphical abstract