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Enhanced ferro-photocatalytic performance for ANbO3 (A = Na, K) nanoparticles

  • Received: 26 February 2019 Accepted: 27 April 2019 Published: 10 May 2019
  • In this study, NaNbO3 with average grain size of ~50 nm and KNbO3 with average grain size of ~300 nm nanocrystals are prepared by the water-based citrate precursor sol-gel process. However, the KNbO3 sample exhibits better photocatalytic performance than that of the NaNbO3 sample by Rh B degradation experiment. By Rietveld refinements and piezoelectric displacement measurements, the KNbO3 with the space group of Bmm2 is ferroelectric while the NaNbO3 with the space group of Pbma is antiferroelectric. The polarization-modulated built-in electric fields in the ferroelectric KNbO3 nanoparticles can efficiently enhance the separation of photo-generated charge carries and thus improve the photocatalytic activity. However, there is no internal electric field in the antiferroelectric grain because of the antiparallel spontaneous polarization in the adjacent unit cell. Therefore, KNbO3 exhibits better oxidizing ability of organic dyes than NaNbO3. The ferroelectric KNbO3 nanoparticles exhibit an optimum photocatalytic performance for a complete degradation of Rh B in 100 min under UV-Vis light irradiation with auxiliary ultrasonic excitation. This study demonstrates that the perovskite-type ferroelectric nanocrystals are potentially to design high-performance catalysts for degradation of contaminant.

    Citation: Yu Huan, Hengtao Shen, Yuanna Zhu, Min Li, Hangyu Li, Zhenxing Wang, Yanan Hao, Tao Wei. Enhanced ferro-photocatalytic performance for ANbO3 (A = Na, K) nanoparticles[J]. Mathematical Biosciences and Engineering, 2019, 16(5): 4122-4134. doi: 10.3934/mbe.2019205

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  • In this study, NaNbO3 with average grain size of ~50 nm and KNbO3 with average grain size of ~300 nm nanocrystals are prepared by the water-based citrate precursor sol-gel process. However, the KNbO3 sample exhibits better photocatalytic performance than that of the NaNbO3 sample by Rh B degradation experiment. By Rietveld refinements and piezoelectric displacement measurements, the KNbO3 with the space group of Bmm2 is ferroelectric while the NaNbO3 with the space group of Pbma is antiferroelectric. The polarization-modulated built-in electric fields in the ferroelectric KNbO3 nanoparticles can efficiently enhance the separation of photo-generated charge carries and thus improve the photocatalytic activity. However, there is no internal electric field in the antiferroelectric grain because of the antiparallel spontaneous polarization in the adjacent unit cell. Therefore, KNbO3 exhibits better oxidizing ability of organic dyes than NaNbO3. The ferroelectric KNbO3 nanoparticles exhibit an optimum photocatalytic performance for a complete degradation of Rh B in 100 min under UV-Vis light irradiation with auxiliary ultrasonic excitation. This study demonstrates that the perovskite-type ferroelectric nanocrystals are potentially to design high-performance catalysts for degradation of contaminant.


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    [1] S. Xu, L. Guo, Q. Sun, et al., Piezotronic effect enhanced Plasmonic photocatalysis by AuNPs/BaTiO3 heterostructures, Adv. Funct. Mater., 1 (2019), 1808737.
    [2] G. N. Wang, P. Wang, H. K. Luo, et al., Novel Au/La-SrTiO3 microspheres: superimposed effect of gold nanoparticles and lanthanum soping in photocatalysis, Chem. Asian J., 9 (2014), 1854–1859.
    [3] D. Yu, Z. Liu, J. Zhang, et al., Enhanced catalytic performance by multi-field coupling in KNbO3 nanostructures: Piezo-photocatalytic and ferro-photoelectrochemical effects, Nano Energy, 58 (2019), 695–705.
    [4] X. Zhang, Y. Huan, K. Li, et al., Enhanced photocatalytic activity and cycle stability driven by ultrasonic vibration for ferroelectric photocatalysts, IET Nanodielectr., 2 (2019), 48–53.
    [5] C. C. Hu, C. C. Tsai and H. S. Teng, Structure characterization and tuning of perovskite-like NaTaO3 for applications in photoluminescence and Photocatalysis, J. Am. Ceram. Soc., 92 (2009), 460–466.
    [6] F. Gao, Y. Yuan, K. Wang, et al., Preparation and photoabsorption characterization of BiFeO3 nanowires, Appl. Phys. Lett., 89 (2006), 102506.
    [7] D. Arney, T. Watkins and P. A. Maggard, Effects of particle surface areas and microstructures on photocatalytic H2 and O2 production over PbTiO3, J. Am. Ceram. Soc., 94 (2011), 1483–1489.
    [8] E. Grabowska, Selected perovskite oxides: Characterization, preparation and photocatalytic properties: A review, Appl. Catal. B-Environ., 186 (2016), 97–126.
    [9] B. Cui, P. Werner, T. Ma, et al., Direct imaging of structural changes induced by ionic liquid gating leading to engineered three-dimensional meso-structures, Nat. Commun., 9 (2018), 3055.
    [10] Y. Huan, X. S. Zhang, J. N. Song, et al., High-performance piezoelectric composite nanogenerator based on Ag/(K,Na)NbO3 heterostructure, Nano Energy, 50 (2018), 62–69.
    [11] Z. Feng, Y. Hao, M. Bi, et al., Highly dispersive Ba0.6Sr0.4TiO3 nanoparticles modified P(VDF-HFP)/PMMA composite films with improved energy storage density and efficiency, IET Nanodielectr., 1 (2018), 60–66.
    [12] K. Motoo, F. Arai, T. Fukuda, et al., Touch sensor for micromanipulation with pipette using lead-free (K,Na)(Nb,Ta)O3 piezoelectric ceramics, J. Appl. Phys., 98 (2005), 094505.
    [13] Y. Huan, T. Wei, Z. Wang, et al., Polarization switching and rotation in KNN-based lead-free piezoelectric ceramics near the polymorphic phase boundary, J. Eur. Ceram. Soc., 39 (2019), 1002–1010.
    [14] T. Dippong, O. Cadar, E. A. Levei, et al., Effect of annealing on the structure and magnetic properties of CoFe2O4:SiO2 nanocomposites, Ceram. Int., 43 (2017), 9145–9152.
    [15] T. Dippong, E. A. Levei, O. Cadar, et al., Sol-gel synthesis of CoFe2O4:SiO2 nanocomposites-insights into the thermal decomposition process of precursors, J. Anal. Appl. Pyrolysis, 125 (2017), 169–177.
    [16] T. Dippong, E. A. Levei, O. Cadar, et al., Thermal behavior of CoxFe3−xO4/SiO2 nanocomposites obtained by a modified sol–gel method, J. Therm. Anal. Calorim., 128 (2017), 39–52.
    [17] C. C. Chen, W. H. Ma and J. C. Zhao, Semiconductor-mediated photodegradation of pollutants under visible-light irradiation, Chem. Soc. Rev., 39 (2010), 4206–4219.
    [18] L. Guo, J. Deng, G. Wang, et al., Zn–air batteries: N, P-doped CoS2 embedded in TiO2 nanoporous films for Zn–Air batteries, Adv. Funct. Mater., 28 (2018), 1870301.
    [19] T. Dippong, D. Toloman, E. A. Levei, et al., A possible formation mechanism and photocatalytic properties of CoFe2O4/PVA-SiO2 nanocomposites, Thermochim. Acta, 666 (2018), 103–115.
    [20] P. Zhou, J. G. Yu and M. Jaroniec, All-solid-state Z-scheme photocatalytic systems, Adv. Mater., 26 (2014), 4920–4935.
    [21] S. Rawalekar and T. Mokari, Rational design of hybrid nanostructures for advanced photocatalysis, Adv. Funct. Mater., 3 (2013), 12–27.
    [22] T. Trindade, P. O'Brien and N. L. Pickett, Nanocrystalline semiconductors: Synthesis, properties, and perspectives, Chem. Mater., 13 (2001), 3843–3858.
    [23] J. Y. Lan, X. Zhou, G. Liu, et al., Enhancing photocatalytic activity of one-dimensional KNbO3 nanowires by Au nanoparticles under ultraviolet and visible-light, Nanoscale, 3 (2011), 5161–5167.
    [24] X. Zhang, Y. Huan, Y. Zhu, et al., Enhanced photocatalytic activity by the combined influence of ferroelectric domain and Au nanoparticles for BaTiO3 fibers, Nano, 13 (2018), 1850149.
    [25] T. Dippong, E. A. Levei, O. Cadar, et al., Size and shape-controlled synthesis and characterization of CoFe2O4 nanoparticles embedded in a PVA-SiO2 hybrid matrix, J. Anal. Appl. Pyrolysis, 128 (2017), 121–130.
    [26] Y. Huan, X. Wang, W. Hao, et al., Enhanced photocatalysis activity of ferroelectric KNbO3 nanofibers compared with antiferroelectric NaNbO3 nanofibers synthesized by electrospinning, Rsc Adv., 5 (2015), 72410–72415.
    [27] T. T. Zhang, K. Zhao, J. G. Yu, et al., Photocatalytic water splitting for hydrogen generation on cubic, orthorhombic, and tetragonal KNbO3 microcubes, Nanoscale, 5 (2013), 8375–8383.
    [28] Y. I. Yuzyuk, P. Simon, E. Gagarina, et al., Modulated phases in NaNbO3: Raman scattering, synchrotron X-ray diffraction, and dielectric investigations, J. Phys. Condens. Matter, 17 (2005), 4977–4990.
    [29] C. Chaker, W. El Gharbi, N. Abdelmoula, et al., Na1-xLixNbO3 ceramics studied by X-ray diffraction, dielectric, pyroelectric, piezoelectric and Raman spectroscopy, J. Phys. Chem. Solid, 72 (2011), 1140–1146.
    [30] T. Y. Ke, H. A. Chen, H. S. Sheu, et al., Sodium niobate nanowire and its piezoelectricity, J. Phys. Chem. C, 112 (2008), 8827–8831.
    [31] H. You, X. Ma, Z. Wu, et al., Piezoelectrically/pyroelectrically-driven vibration/cold-hot energy harvesting for mechano-/pyro-bi-catalytic dye decomposition of NaNbO3 nanofibers, Nano Energy, 52 (2018), 351–359.
    [32] J. Tauc, R. Grigorovici and A. Vancu, Optical properties and electronic structure of amorphous germanium, Phys. Status Solidi, 3 (1966), 37–46.
    [33] C. Dong, C. Lian, S. Hu, et al., Size-dependent activity and selectivity of carbon dioxide photocatalytic reduction over platinum nanoparticles, Nat. Commun., 9 (2018), 1252.
    [34] J. Wang, L. Tang, G. Zeng, et al., 0D/2D interface engineering of carbon quantum dots modified Bi2WO6 ultrathin nanosheets with enhanced photoactivity for full spectrum light utilization and mechanism insight, Appl. Catal. B Environ., 222 (2018), 115–123.
    [35] Y. Deng, L. Tang, G. Zeng, et al., Plasmonic resonance excited dual Z-scheme BiVO4/Ag/Cu2O nanocomposite: synthesis and mechanism for enhanced photocatalytic performance in recalcitrant antibiotic degradation, Environ. Sci. Nano, 4 (2017), 1494–1511.
    [36] B. Cui, C. Song, H. J. Mao, et al., Magnetoelectric coupling induced by interfacial orbital reconstruction, Adv. Mater., 27 (2015), 6651–6656.
    [37] J. Wu, N. Qin and D. Bao, Effective enhancement of piezocatalytic activity of BaTiO3 nanowires under ultrasonic vibration, Nano Energy, 45 (2018), 44–51.
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