Formation and role in gas sensing properties of spherical and hollow silver nanoparticles deposited on the surface of electrochemically exfoliated graphite

[Display omitted] •Outlined a new synthetic method for electrochemically exfoliated graphite (EEG) using KIO3 as the electrolyte.•The high mobility of I- ions caused fast expansion of graphene layers in graphite.•The synthesis of EEG@Ag nanocomposites methods was developed, including synthesis of ho...

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Published in:Applied surface science 2022-04, Vol.580, p.152316, Article 152316
Main Authors: Łukowiec, Dariusz, Kubacki, Jerzy, Kałużyński, Piotr, Procek, Marcin, Wacławek, Stanisław, Radoń, Adrian
Format: Article
Language:English
Subjects:
Electrochemical exfoliation
Gas sensor
Graphene oxide
N-type semiconductor
NO2 sensing mechanism
P-type semiconductor
Silver nanoparticles
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Summary:[Display omitted] •Outlined a new synthetic method for electrochemically exfoliated graphite (EEG) using KIO3 as the electrolyte.•The high mobility of I- ions caused fast expansion of graphene layers in graphite.•The synthesis of EEG@Ag nanocomposites methods was developed, including synthesis of hollow spheres.•The NO2 sensing properties of EEG@Ag nanocomposites exceeded those of bare EEG.•The conductivity of EEG@Ag nanocomposites switched from p-type to n-type in the presence of high concentrations of NO2 (>50 ppm).•The density of state at Fermii level for EEG@Aghollow nanocomposite is greater than for EEG@Agspherical which may explain the improved dynamic performance of the first composite. Synthetic methods to produce electrochemically exfoliated graphite (EEG) and composites containing silver nanoparticles (AgNPs) deposited on the EEG surface are discussed. An aqueous solution KIO3 was used as the electrolyte for the first time; therefore, oxidation and exfoliation mechanisms are described and discussed in detail. The graphite-based nanostructures were characterized by high stability in water and ethanol dispersions. Two composites with spherical or hollow-shaped ultra-fine AgNPs were synthesized and their structure and physicochemical properties are described. Use of CaCl2 with NaBH4 resulted in the formation of hollow nanoparticles on the EEG surface, whereas simple photoreduction synthesized ultra-fine nanoparticles. The role of silver nanoparticles attached to EEG on the gas sensing properties (for NO2) at different temperatures was determined. Gas sensing experiments confirmed that relatively low levels of AgNPs (1.36% and 6.16% for hollow and spherical NPs, respectively) improved the NO2 sensing properties of EEG. Moreover, at higher temperatures (150 °C) and relatively high NO2 concentrations (>50 ppm), the conductivities of both composites switched from p-type to n-type. The composite with a lower nanoparticle loading (1.56 at%) but larger size showed a significantly better dynamic parameters (response and recovery time).
ISSN:0169-4332
1873-5584
1873-5584
DOI:10.1016/j.apsusc.2021.152316