Grow p-type MoS2 on FeNC for CO2 Sensing in Complex Environments with Intelligent Recognition
Artikel i vetenskaplig tidskrift, 2026

A wealth of theoretical studies demonstrates p-type MoS2 (p-MoS2) as a promising candidate for carbon dioxide (CO2) detection at room temperature. Its applications are retarded by issues associated with its practical chemical synthesis and sensing selectivity. Herein, a chemically tunable strategy is established for in situ growth of p-MoS2 with controlled thickness and n-/p-type transition on N- and Fe-enriched carbon (FeNC) nanosheets. The introduced sulfur vacancies (Svacs) enhance the sensitivity to CO2, and the modulated electron distribution suppresses surface oxygen ionization to improve sensing selectivity. The optimized p-type composites can detect CO2 fluctuation levels as low as 50 ppm at room temperature. Density functional theory (DFT) and grand canonical Monte Carlo (GCMC) simulations clarify the underlying mechanisms. A visualized machine learning (ML) model is developed using a hybrid ML strategy that generates regression surfaces from linear/nonlinear data. Through this model, a single sensor accurately discriminates CO2 from interfering and predicts its concentration and humidity with accuracies exceeding 95%. An intelligent sensing system capable of environmental monitoring and tracking exhaled CO2 is demonstrated. The measured fluctuations strongly correlate with physiological indicators, underscoring their potential for non-invasive health monitoring and medical diagnostics.

CO2 sensing

cross-sensitivity

P-type MoS2

machine learning

gas prediction

Författare

Yuefeng Gu

Stockholms universitet

Xiamen University

Yuhao Wang

Xiamen University

Jing Ai

Stockholms universitet

Gongjie Liu

Xiamen University

Sadaf Saeedi Garakani

Chalmers, Kemi och kemiteknik, Kemiteknik

Forskning Andra publikationer

Lisi Wei

Xiamen University

Zeen Wu

Stockholms universitet

Jiayin Yuan

Stockholms universitet

Qiuhong Li

Xiamen University

Advanced Science

2198-3844 (ISSN) 21983844 (eISSN)

Vol. 13 1 e12595

Ämneskategorier (SSIF 2025)

Materialkemi

Den kondenserade materiens fysik

Styrkeområden

Materialvetenskap

DOI

10.1002/advs.202512595

Publikationsdata kopplat till DOI

PubMed

41133926

Mer information

Senast uppdaterat

2026-01-20

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