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
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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cHCl=(a) 8 mol·L-1, (b) 12 mol·L-1; Hydrothermal reaction temper-ature: 220 ℃; Hydrothermal reaction time: 30 h
cHCl=(a) 8 mol·L-1, (b) 12 mol·L-1; Hydrothermal reaction temperature: 220 ℃; Hydrothermal reaction time: 30 h
cHCl=(a, c) 8 mol·L-1, (b, d) 12 mol·L-1; Hydrothermal reaction temperature: 220 ℃; Hydrothermal reaction time: 30 h
cHCl=(a) 8 mol·L-1, (b) 12 mol·L-1; Hydrothermal reaction tempera-ture: 220 ℃; Hydrothermal reaction time: 30 h
cHCl=(a) 8 mol·L-1, (b) 12 mol·L-1; Hydrothermal reaction temper-ature: 220 ℃; Hydrothermal reaction time: 30 h
cHCl=(a) 8 mol·L-1, (b) 12 mol·L-1; Hydrothermal reaction temper-ature: 220 ℃; Hydrothermal reaction time: 30 h; Irradiation condi-tion: 50 W halogen lamp, 10 s, 15 times; Inset: pictures of Cs0.2WO3 powder
(a)cWCl6=8 mmol·L-1 in n-propanol, (b) cWCl6=10 mmol·L-1 in ethanol; Hydrothermal reaction temperature: 200 ℃; Hydrothermal reaction time: 20 h
(a, c) cWCl6=8 mmol·L-1 in n-propanol, (b, d) cWCl6=10 mmol·L-1 in ethanol; Hydrothermal reaction temperature: 200 ℃; Hydrothermal reaction time: 20 h
(a) cWCl6=8 mmol·L-1 in n-propanol, (b) cWCl6=10 mmol·L-1 in ethanol; Hydrothermal reaction temperature: 200 ℃; Hydrothermal reaction time: 20 h
(a) cWCl6=8 mmol·L-1 in n-propanol, (b) cWCl6=10 mmol·L-1 in ethanol; Hydrothermal reaction temperature: 200 ℃; Hydrothermal reaction time: 20 h; Irradiation condition: 50 W halogen lamp, 10 s, 15 times; Inset: picture of W18O49 powder