Amorphous/Crystal Heterostructure Coupled Oxygen Vacancies‐Sensitized TiO2 with Conspicuous Charge‐Transfer Resonance for Efficient SERS Detection of Chloramphenicol

Abstract Antibiotic environmental pollutants, such as chloramphenicol (CAP), have attracted global attention. They usually show a complex background, low concentration, and weak chemical activity in water bodies, making their rapid and on‐site detection a scientific challenge. Surface‐enhanced Raman spectroscopy (SERS) technology can facilitate the practical application of CAP detection; however, it is important to match substrate materials with excellent SERS properties. The most challenging aspect of SERS substrate design is the realization of energy level matching and charge‐transfer resonance. Herein, a crystal‐amorphous TiO 2 substrate material rich in oxygen vacancies, CA‐V‐TiO 2 , is proposed. Through the cooperative regulation of vacancies and amorphous state, the bandgap structure can be optimized, the charge‐transfer efficiency can be improved, and finally the energy level matching between CA‐V‐TiO 2 substrate and molecules can be realized and the conspicuous charge‐transfer resonance phenomenon can be generated, effectively optimizing the performance of SERS substrate. In addition, CA‐V‐TiO 2 substrate is used for sensitive detection of CAP, showing multiple advantages such as low detection limit, good reproducibility, and high stability, which can realize trace CAP detection in actual water environments. This work provides a reliable platform for SERS on‐site detection of CAP in the field of food and environmental monitoring.