磷光
化学
余辉
信号(编程语言)
干扰(通信)
基质(化学分析)
光电子学
三元运算
兴奋剂
线性判别分析
三唑
分析化学(期刊)
二进制数
传感器阵列
激发态
生物系统
分子
化学计量学
硼酸
光学滤波器
多路复用
作者
Song Shen,C Q Liu,H J Wang,Jinzhu Ma,Yun‐Kai Lv,Y. D. Wang,Dafeng Jiang,Zhenguang Wang
标识
DOI:10.1021/acs.analchem.6c00501
摘要
Detection and discrimination of structurally similar triazole fungicide (TF) subtypes remain highly desirable yet challenging. This work presents a straightforward room-temperature phosphorescence (RTP) sensor array for the visual discrimination of TFs, based on host-guest doping-induced RTP signal amplification. Five TF subtypes were doped into a boric acid (BA) matrix via thermal treatment, yielding intense, multicolored, and long-lived afterglow composites. The rigid BA matrix amplified the phosphorescence of guest molecules by reducing the singlet-triplet energy gap and suppressing nonradiative decay. The composites exhibited concentration-dependent RTP fingerprints in terms of emission color, intensity, and lifetime, enabling the discrimination of TFs, including binary and ternary mixtures, through linear discriminant analysis and hierarchical cluster analysis. Time-resolved RTP signal collection effectively eliminated background interference from autofluorescence and scattering, ensuring robust detection in real samples. Furthermore, an intelligent artificial vision platform utilizing the DenseNet algorithm achieved automated identification of TF types and concentrations directly from afterglow images with high accuracy (>91%) and speed (<1 s). This study offers a visual strategy for trace-level TF discrimination, demonstrating significant potential for on-site environmental and food safety monitoring.
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