Details

Autor(en) / Beteiligte

• Shinde, Rohini B.
• Padalkar, Navnath S.
• Sadavar, Shrikant V.
• Kale, Shital B.
• Magdum, Vikas V.
• Chitare, Yogesh M.
• Kulkarni, Shirin P.
• Patil, Umakant M.
• Parale, Vinayak G.
• Park, Hyung-Ho
• Gunjakar, Jayavant L.

Titel

2D–2D lattice engineering route for intimately coupled nanohybrids of layered double hydroxide and potassium hexaniobate: Chemiresistive SO2 sensor

Ist Teil von

• Journal of hazardous materials, 2022-06, Vol.432, p.128734-128734, Article 128734

Ort / Verlag

Elsevier B.V

Erscheinungsjahr

2022

Quelle

Access via ScienceDirect (Elsevier)

Beschreibungen/Notizen

• 2D–2D lattice engineering route is used to synthesize intimately coupled nanohybrids of layered double hydroxide (LDH) and potassium hexaniobate. The 2D–2D lattice engineering route is based on the electrostatically derived self-assembly of delaminated zinc-chromium-layered double hydroxide (ZC-LDH) nanosheets and potassium hexaniobate (HNb) nanosheets (ZCNb nanohybrids). The 2D–2D lattice-engineered ZCNb nanohybrids display expanded surface area, mesoporous anchored nanosheets network morphology, and intimate coupling between nanosheets. The 2D–2D lattice engineered ZCNb nanohybrids are used for the low temperature operated gas sensor. The ZCNb nanohybrids display outstanding selectivity for the SO2, with the high response of 61.5% compared to pristine ZC-LDH (28.08%) and potassium niobate (8%) at 150 °C. Moreover, ZCNb sensors demonstrate superior response and recovery periods of 6 and 167 s at 150 °C, respectively. This result underscores the exceptional functionality of the ZCNb nanohybrids as efficient SO2 sensors. Moreover, these findings vividly demonstrate that the 2D–2D lattice-engineered ZCNb nanohybrids are quite effective not only in improving the gas sensor activity but also in developing of new type of intimately coupled mesoporous LDH-metal-oxide based hybrid materials. [Display omitted] •Nanohybrids of ZC-LDH and HNb (ZCNb) nanosheets are prepared via lattice-engineered self-assembly method.•ZCNb nanohybrids shows high surface area mesoporous structure.•The ZCNb nanohybrids shows excellent sensitivity for the detection of SO2 at 150 °C.•The enhanced SO2 sensing performance of ZCNb nanohybrids is attributed to porous microstructure and expanded surface area.