TY - JOUR
T1 - Radial-Hierarchical Chromatomimetic E-Nose for Spatiotemporal VOC Diffusion Mapping
AU - Zhai, Xingchun
AU - Li, Junjie
AU - Cheng, Weiwei
AU - Li, Xiaolu
AU - Zhang, Yongheng
AU - Cao, Bingxue
AU - Wen, Junjie
AU - Zhu, Ninghui
AU - Wu, Da
AU - Wang, Tao
AU - Xuan, Fuzhen
AU - Shi, Guoyue
AU - Zhang, Min
N1 - Publisher Copyright:
© 2025 American Chemical Society
PY - 2025/9/9
Y1 - 2025/9/9
N2 - This study introduces a radial-hierarchical, diffusion-enhanced spatiotemporal sensing paradigm for volatile organic compound (VOC) analysis via an integrated microchamber paper-based chromatomimetic e-nose. The proposed system synergizes interlayer spatiotemporal dynamics with planar spatial variance by employing a radially symmetric electrode array and a hierarchical porous chemoresistive ink (CuP@G). This design leverages molecular diffusion gradients across the sensing plane, enabling precise discrimination of complex VOC mixtures through multidimensional “spatiotemporal fingerprints”. A physics-informed framework integrates molecular transport principles with multitask learning convolutional neural network (MTL-CNN) analytics, achieving unprecedented resolution in real-sample classification. Systematic validation demonstrates superior performance in discriminating diverse VOCs, binary mixtures, and authentic tobacco samples (origin and level classification accuracy: 92–99%). This work establishes a scalable blueprint for high-fidelity VOC analytics, bridging gas diffusion physics with intelligent signal processing to advance e-nose technology toward precision-driven design.
AB - This study introduces a radial-hierarchical, diffusion-enhanced spatiotemporal sensing paradigm for volatile organic compound (VOC) analysis via an integrated microchamber paper-based chromatomimetic e-nose. The proposed system synergizes interlayer spatiotemporal dynamics with planar spatial variance by employing a radially symmetric electrode array and a hierarchical porous chemoresistive ink (CuP@G). This design leverages molecular diffusion gradients across the sensing plane, enabling precise discrimination of complex VOC mixtures through multidimensional “spatiotemporal fingerprints”. A physics-informed framework integrates molecular transport principles with multitask learning convolutional neural network (MTL-CNN) analytics, achieving unprecedented resolution in real-sample classification. Systematic validation demonstrates superior performance in discriminating diverse VOCs, binary mixtures, and authentic tobacco samples (origin and level classification accuracy: 92–99%). This work establishes a scalable blueprint for high-fidelity VOC analytics, bridging gas diffusion physics with intelligent signal processing to advance e-nose technology toward precision-driven design.
UR - https://www.scopus.com/pages/publications/105015466003
U2 - 10.1021/acs.analchem.5c04223
DO - 10.1021/acs.analchem.5c04223
M3 - 文章
AN - SCOPUS:105015466003
SN - 0003-2700
VL - 97
SP - 19380
EP - 19387
JO - Analytical Chemistry
JF - Analytical Chemistry
IS - 35
ER -