Three-Dimensional van der Waals Heterostructure-Based Nanocages as Supersensitive 3-Hydroxy-2-butanone Gas Sensors at Room Temperature

Abstract: 3-Hydroxy-2-butanone is one of the biomarkers of Listeria monocytogenes, which is quite important for the intelligent detection of 3H-2B. However, it is still a challenge to fabricate sensing materials obtaining excellent sensitivity and selectivity under the ppb-level detection limit. Herein, a plasma-assisted synthetic approach was proposed for the construction of hierarchical nanostructures and the simultaneous loading of TAPP-COFs, which could reduce interlayer interaction and convert the metallized sites … Show more

“…37 Other different types of defects have already been characterized by EPR spectroscopy, providing a new insight into gas sensing materials and the corresponding underlying sensing mechanisms (Table 3). [38][39][40][41][42][43][44][45][46][47][48][49][50][51][52][53][54] Table 3 Summary of typical gas sensing materials and the corresponding EPR results…”

“…37 Other different types of defects have already been characterized by EPR spectroscopy, providing a new insight into gas sensing materials and the corresponding underlying sensing mechanisms (Table 3). 38–54…”

Behind the gas sensors: revealing sensing mechanisms with advanced magnetic resonance technology

“…37 Other different types of defects have already been characterized by EPR spectroscopy, providing a new insight into gas sensing materials and the corresponding underlying sensing mechanisms (Table 3). [38][39][40][41][42][43][44][45][46][47][48][49][50][51][52][53][54] Table 3 Summary of typical gas sensing materials and the corresponding EPR results…”

“…37 Other different types of defects have already been characterized by EPR spectroscopy, providing a new insight into gas sensing materials and the corresponding underlying sensing mechanisms (Table 3). 38–54…”

Behind the gas sensors: revealing sensing mechanisms with advanced magnetic resonance technology

“…Herein, we study the effect of plasma treatment of tin dioxide films on their surface and photocatalytic properties, which are selected for analysis due to their close relationship with the adsorption and sensor functionalities. While such processing is frequently employed as a manufacturing operation to produce semiconductor devices [15][16][17][18], it has also been found that oxygen plasma treatment improves the performance of metal oxide gas sensors [13,19,20]. The analysis of literature sources also shows that plasma treatment leads to a significant improvement in the photocatalytic properties of semiconductor oxides.…”

Effects of Plasma Treatment on the Surface and Photocatalytic Properties of Nanostructured SnO2–SiO2 Films

Self-standing perylene diimide covalent organic framework membranes for trace TMA sensing at room temperature