以Fe(NO)3·9H2 O和KOH为原料, 在100℃下水热反应6h制备了α-FeOOH纳米棒, 并在不同温度下对其进行热处理, 得到具有一维纳米孔结构的α-Fe2O3单晶. 用XRD和TEM对α-FeOOH和热处理产物α-Fe2O3的物相、形貌进行表征, 并结合TGA和FT-IR研究了α-FeOOH的热处理过程. 结果表明, α-FeOOH在239~295℃温度区间发生脱水相变α-FeOOH→α-Fe2O3. 纳米α-Fe2O3很好地保持棒状, 但在其表面出现了孔洞, 随着温度的升高孔洞趋于愈合. 采用DTA考察了α-Fe2O3纳米棒对高氯酸铵(AP)的催化作用. 不同温度下热处理得到的α-Fe2O3均使AP的高温分解温度显著降低, 其中350℃热处理得到的α-Fe2O3纳米棒使AP高温分解温度最大降幅达71.4℃.
The α-FeOOH nanorods were prepared via hydrothermal reaction of Fe(NO3)3·9H2O and KOH at
100℃ for 6h. Then the α-FeOOH nanords were heat treated at different temperautres, and single crystalline and multiporous α-Fe2O3 nanorods were obtained. The phase and morphology of the samples were characterized by XRD and TEM. The heat treatment process was investigated by TGA and FT-IR. The results show that the phase transition of α-FeOOH→α-Fe2O3 occurrs between 239℃ and 259.1℃. The α-Fe2O3 still keeps in rod shape and lots of holes appear on the surface which disappear with the temperature increasing. The catalytic performance of α-Fe2O3 nanorods was studied by decomposition of ammonium perchlorate(AP) based on DTA. The higher-temperature of exothermic peak of AP shifts towards low temperature when α-Fe2O3 nanorods are introduced into the reaction, and the largest decrement reaches 71.4℃ for the α-Fe2O3 nanorods heat treated at 350℃.
参考文献
| [1] | Kalarical Janardhanan Sreeram, Ramasamy Indumathy, Ananthanarayanan Rajaram, et al. Mater. Res. Bull., 2006, 41 (10): 1875--1881. [2] Rumyantseva M, Kovalenko V, Gaskov A, et al. Comini. Sens. Actuator B-Chem., 2007, 118 (1-2): 208--214. [3] Khedr M H, Abdel Halim K S, Nasr M I, et al. Mater. Sci. Eng. A, 2006, 430 (1-2): 40--45. [4] Sreeja V, Joy P A. Mater. Res. Bull., 2007, 42 (8): 1570--1576. [5] Diamandescu L, Mihaila-Tarabasanu D, Calogero S, et al. M. Feder. Solid State Ion., 1997, 101-103 (1): 591--596. [6] 钭启升, 张辉, 邬剑波(DOU Qing-Sheng, et al). 无机材料学报(Journal of Inorganic Materials), 2007, 22 (2): 213--218. [7] 孟哲, 贾振斌, 魏雨. 过程工程学报, 2004, 4 (2): 146--149. [8] Music S, Krehula S, Popovic S. Mater. Lett., 2004, 58 (3-4): 444--448. [9] Adam S J Baker, Adrian S C Brown, Martin A Edwards, et al. J. Mater. Chem., 2000, 10 (3): 761--766. [10] 陈济舟, 蒋世承, 王加林, 等. 应用科学学报, 1990, 8 (1): 55--60. [11] Zheng Yuanhui, Cheng Yao, Wang Yuansheng, et al. J. Phys. Chem. B, 2006, 110 (7): 3093--3097. [12] 陈伟凡, 李凤生, 刘建勋, 等. 催化学报, 2005, 26 (12): 1073--1077. [13] 马振叶, 李凤生. 固体火箭技术, 2006, 29 (4): 286--288. [14] Cheng Tao, Fang Zhiyong, Hu Qixiu, et al. Catal. Commun, 2007, 8 (7): 1167--1171. |
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