Journal of Inorganic Materials, Volume. 38, Issue 10, 1216(2023)

α-Ni(OH)2 Surface Hydroxyls Synergize Ni3+ Sites for Catalytic Formaldehyde Oxidation

Ruiyang ZHANG1...2, Yi WANG1,2, Bowen OU2, and Ying ZHOU12,* |Show fewer author(s)
Author Affiliations
  • 11. National Key Laboratory of Oil and Gas Reservoir Geology and Exploitation, Southwest Petroleum University, Chengdu 610500, China
  • 22. School of New Energy and Materials, Southwest Petroleum University, Chengdu 610500, China
  • show less
    References(39)

    [1] D BOURDIN, P MOCHO, V DESAUZIERS et al. Formaldehyde emission behavior of building materials: on-site measurements and modeling approach to predict indoor air pollution. Journal of Hazardous Materials, 280: 164(2014).

    [5] W KIM, S A YOUNIS, K KIM. The control on adsorption kinetics and selectivity of formaldehyde in relation to different surface- modification approaches for microporous carbon bed systems. Separation and Purification Technology, 283: 120178(2022).

    [7] K VIKRANT, K KIM, F DONG et al. Deep oxidation of gaseous formaldehyde at room-temperature by a durable catalyst formed through the controlled addition of potassium to platinum supported on waste eggshell. Chemical Engineering Journal, 428: 131177(2022).

    [12] J JI, X LU, C CHEN et al. Potassium-modulated δ-MnO2 as robust catalysts for formaldehyde oxidation at room temperature. Applied Catalysis B: Environmental, 260: 118210(2020).

    [15] S ZHU, J ZHENG, S XIN et al. Preparation of flexible Pt/TiO2/ γ-Al2O3 nanofiber paper for room-temperature HCHO oxidation and particulate filtration. Chemical Engineering Journal, 427: 130951(2022).

    [18] M YANG, J ZHANG, W ZHANG et al. Pt nanoparticles/Fe-doped α-Ni(OH)2 nanosheets array with low Pt loading as a high- performance electrocatalyst for alkaline hydrogen evolution reaction. Journal of Alloys and Compounds, 823: 153790(2020).

    [21] A ZHANG, R ZHANG, L FEI et al. Tunable microstructure of α-Ni(OH)2 for highly-efficient surface adsorbates activation to promote catalytic NO oxidation. Chemical Engineering Journal, 425: 130663(2021).

    [22] R ZHANG, T RAN, Y CAO et al. Oxygen activation of noble- metal-free g-C3N4/α-Ni(OH)2 to control the toxic byproduct of photocatalytic nitric oxide removal. Chemical Engineering Journal, 382: 123029(2020).

    [23] D JIA, H GAO, W DONG et al. Hierarchical α-Ni(OH)2 composed of ultrathin nanosheets with controlled interlayer distances and their enhanced catalytic performance. ACS Applied Materials & Interfaces, 20476(2017).

    [24] H LI, C RAMESHAN, A V BUKHTIYAROV et al. CO2 activation on ultrathin ZrO2 film by H2O co-adsorption: in situ NAP-XPS and IRAS studies. Surface Science, 679: 139(2019).

    [25] J ZHU, J YANG, J ZHOU et al. A stable organic-inorganic hybrid layer protected lithium metal anode for long-cycle lithium-oxygen batteries. Journal of Power Sources, 366: 265(2017).

    [31] X YANG, H ZHANG, W XU et al. A doping element improving the properties of catalysis: in situ Raman spectroscopy insights into Mn-doped NiMn layered double hydroxide for the urea oxidation reaction. Catalysis Science & Technology, 4471(2022).

    [33] G LAN, J LI, G ZHANG et al. Thermal decomposition mechanism study of 3-nitro-1, 2, 4-triazol-5-one (NTO): combined TG-FTIR- MS techniques and ReaxFF reactive molecular dynamics simulations. Fuel, 295: 120655(2021).

    [34] H XUE, C WANG, A MAHMOOD et al. Two-dimensional g-C3N4 compositing with Ag-TiO2 as deactivation resistant photocatalyst for degradation of gaseous acetaldehyde. Journal of Inorganic Materials, 865(2022).

    [38] H WANG, W GUO, Z JIANG et al. New insight into the enhanced activity of ordered mesoporous nickel oxide in formaldehyde catalytic oxidation reactions. Journal of Catalysis, 361: 370(2018).

    [39] C WANG, X ZOU, H LIU et al. A highly efficient catalyst of palygorskite-supported manganese oxide for formaldehyde oxidation at ambient and low temperature: performance, mechanism and reaction kinetics. Applied Surface Science, 486: 420(2019).

    [40] C WANG, Y LI, C ZHANG et al. A simple strategy to improve Pd dispersion and enhance Pd/TiO2 catalytic activity for formaldehyde oxidation: the roles of surface defects. Applied Catalysis B: Environmental, 282: 119540(2021).

    [41] I SONG, H LEE, S W JEON et al. Understanding the dynamic behavior of acid sites on TiO2-supported vanadia catalysts via operando DRIFTS under SCR-relevant conditions. Journal of Catalysis, 382: 269(2020).

    [42] Y BU, Y CHEN, G JIANG et al. Understanding of Au-CeO2 interface and its role in catalytic oxidation of formaldehyde. Applied Catalysis B: Environmental, 260: 118138(2020).

    [43] J CHEN, H TANG, M HUANG et al. Surface lattice oxygen activation by nitrogen-doped manganese dioxide as an effective and longevous catalyst for indoor HCHO decomposition. ACS Applied Materials & Interfaces, 26960(2021).

    Tools

    Get Citation

    Copy Citation Text

    Ruiyang ZHANG, Yi WANG, Bowen OU, Ying ZHOU. α-Ni(OH)2 Surface Hydroxyls Synergize Ni3+ Sites for Catalytic Formaldehyde Oxidation [J]. Journal of Inorganic Materials, 2023, 38(10): 1216

    Download Citation

    EndNote(RIS)BibTexPlain Text
    Save article for my favorites
    Paper Information

    Category:

    Received: Apr. 3, 2023

    Accepted: --

    Published Online: Mar. 6, 2024

    The Author Email: ZHOU Ying (yzhou@swpu.edu.cn)

    DOI:10.15541/jim20230161

    Topics