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Mie Scattering Theory Deduction and Experimental Verification of Correlation Between Length of One-Dimensional Nanomaterials Cs0.2WO3 and W18O49 and Infrared Absorption
- Corresponding author: Rui-Xing LI, rli@buaa.edu.cn
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Citation:
Yuan-Peng XIONG, Fan-Dong KONG, Rui-Xing LI. Mie Scattering Theory Deduction and Experimental Verification of Correlation Between Length of One-Dimensional Nanomaterials Cs0.2WO3 and W18O49 and Infrared Absorption[J]. Chinese Journal of Inorganic Chemistry,
;2021, 37(10): 1764-1772.
doi:
10.11862/CJIC.2021.200
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The research results show size- and shape-dependent infrared absorption properties for binary and ternary tungsten-oxides. However, there is no universal theory in both physical principle and calculation method for binary and ternary tungsten-oxides. In this study, the correlation between the optical absorption characteristics and onedimensional material length was deduced based on Mie scattering theory, and the correlation of tungsten oxide based materials was studied by means of theoretical deductions and experimental verifications. Firstly, from a perspective of deduction and calculation based on Mie scattering theory reveal that increasing the length of both nanoCs0.2WO3 and W18O49 can improve their near-infrared absorption performance. Secondly, the near-infrared absorption performance of synthesized Cs0.2WO3 nanorods and W18O49 nanowires with different lengths was tested. The experimental data is consistent with the theoretical calculations and simulation results. Cs0.2WO3 nanorods and W18O49 nanowires have different trends with particle length between 2 500 and 20 000 nm, and the infrared absorption properties of Cs0.2WO3 nanorods were proportional to particle length. Finally, the photothermal effects of Cs0.2WO3 nanorods and W18O49 nanowires were tested. And the amplification of temperature reached 18.5% and 12.7% with the increase of particle length for both nano-tungsten oxides, respectively.
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Keywords:
- Mie scattering,
- one-dimensional,
- infrared absorption,
- Cs0.2WO3,
- W18O49
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