Fluorine doping-induced oxygen vacancy-rich TiO2 via contact activation for signal boosting in electrochemical sensing

TiO2, as an important member of transition metal oxides, exhibits great potential for the fabrication of sensors while the semi-conductive property of pure TiO2 makes the superior sensitivity and current response difficult to achieve in electroanalysis. Herein, an effective strategy is firstly proposed to realize F doping of TiO2 through a simple room-temperature contact activation. Through the investigation of characterization and electrochemical measurement, we verified the successful F doping and introduction of oxygen vacancies (OVs) into TiO2 and the resulting positive effect on electrochemical sensing performance. Then we fabricated an electrochemical sensor based on F-doped OV-TiO2 and evaluated its potential to be applied for the detection of dopamine hydrochloride (DAH). Benefiting from the adjustment of surface chemical state and microstructure of TiO2, the electrochemical sensor based on F-doped OV-TiO2 showed an approximate 350-fold increased amperometric response towards DAH and exhibited a high sensitivity of 630 mu A mM-1 cm- 2, a wide linear range of 2-682.7 mu M, a low detection limit of 0.13 mu M as well as satisfying reproducibility and stability, which could be used in the detection of DAH in animal feed with high recovery rate. This work proved that the doping of fluorine and the corresponding introduction of oxygen vacancies can be well utilized to adjust the electrical conductivity and catalytic activity of TiO2, which effectively advanced its reliability to be applied in electrochemical sensing and provided an inno-vative strategy to broaden the application of semiconductors in efficient electrochemical detection.