超声辅助法制备银纳米球及其对亚甲基蓝的催化降解研究
Ultrasonic Wave Assisted Synthesis of Silver Nanospheres and Their Catalytic Degradation on Methylene Blue
DOI: 10.12677/AAC.2015.52002, PDF, HTML, XML, 下载: 3,501  浏览: 14,432  科研立项经费支持
作者: 戴 策, 李 庆, 覃礼钊, 林 华, 聂 明, 李 元:西南大学材料与能源学部,重庆
关键词: 银纳米球超声辅助亚甲基蓝催化降解Silver Nanospheres Ultrasonic Wave Assisted Methylene Blue Catalytic Degradation
摘要: 本文以银氨溶液为银源,抗坏血酸(C6H8O6)为还原剂,聚乙烯吡咯烷酮(PVP)为表面活性剂,在超声辅助条件下,采用了简单环保的室温液相还原法制备出了形貌均匀、分散性良好、粒径为300~400 nm的银纳米球,用X射线粉末衍射、能量分散X射线谱、扫描电子显微镜和紫外–可见分光光度计对合成产物进行了表征。通过改变超声时间、PVP的用量和氨水体积来研究产物的形貌变化。分析了银纳米球的生长过程,提出了可能的生长机理。测试了样品对亚甲基蓝的催化降解性能,结果表明,制备的银纳米球对亚甲基蓝有良好的催化降解效果。
Abstract: A facile environmental friendly method has been developed to prepare silver nanospheres with good dispersion and the size in the range of 300 - 400 nm. Silver nanospheres were obtained via the chemical reduction of Tollens’ reagent at room temperature, using ascorbic acid as the reducing agent and polyvinylpyrrolidone (PVP) as the surfactant. The obtained silver nanospheres were characterized by X-ray powder diffraction (XRD), energy dispersive X-ray spectroscopy (EDX), scanning electron microscopy (SEM) and UV-visible spectroscopy (UV-vis). The influence of reaction time and the amount of PVP and ammonium hydroxide on the formation of silver nanospheres was studied. The growth process of silver nanospheres was analyzed and the possible mechanism of crystal growth was proposed. The catalytic degradation activity of the obtained silver nanospheres on methylene blue was also measured. They showed excellent catalytic degradation activity on methylene blue.
文章引用:戴策, 李庆, 覃礼钊, 林华, 聂明, 李元. 超声辅助法制备银纳米球及其对亚甲基蓝的催化降解研究[J]. 分析化学进展, 2015, 5(2): 7-15. http://dx.doi.org/10.12677/AAC.2015.52002

参考文献

[1] You, C.C., Chompoosor, A. and Rotello, V.M. (2007) The biomacromolecule-nanoparticle interface. Nano Today, 2, 34-43.
[2] Steffan, M., Jakob, A., Claus, P. and Lang, H. (2009) Silica supported silver nanoparticles from a silver(I) carboxylate: Highly active catalyst for regioselective hydrogenation. Catalysis Communications, 10, 437-441.
[3] Sun, Y.G., Yin, Y.D., Mayers, B.T., Herricks, T. and Xia, Y.N. (2002) Uniform silver nanowires synthesis by reducing AgNO3 with ethylene glycol in the presence of seeds and poly(vinyl pyrrolidone). Chemistry of Materials, 14, 4736- 4745.
[4] Chen, J.Y., Wang, D.L., Xi, J.F., Au, L., Siekkinen, A., Warsen, A., Li, Z.Y., Zhang, H., Xia, Y.N. and Li, X.D. (2007) Immuno gold nanocages with tailored optical properties for targeted photothermal destruction of cancer cells. Nano Letters, 7, 1318-1322.
[5] Salem, A.K., Searson, P.C. and Leong, K.W. (2003) Multifunctional nanorods for gene delivery. Nature Materials, 2, 668-671.
[6] Mirkin, C.A., Letsinger, R.L., Mucic, R.C. and Storhoff, J.J. (1996) A DNA-based method for rationally assembling nanoparticles into macroscopic materials. Nature, 382, 607-609.
[7] Rastogi, P.K., Ganesan, V. and Krishnamoorthi, S. (2012) Microwave assisted polymer stabilized synthesis of silver nanoparticles and its application in the degradation of environmental pollutants. Materials Science And Engineering B- Advanced Functional Solid-State Materials, 177, 456-461.
[8] Sanpui, P., Chattopadhyay, A. and Ghosh, S.S. (2011) Induction of Apoptosis in Cancer Cells at Low Silver Nanoparticle Concentrations using Chitosan Nanocarrier. Acs Applied Materials & Interfaces, 3, 218-228.
[9] Balavandy, S.K., Shameli, K., Biak, D.R.B.A. and Abidin, Z.Z. (2014) Stirring time effect of silver nanoparticles prepared in glutathione mediated by green method. Chemistry Central Journal, 8.
[10] Gonzalez, C.M., Liu, Y. and Scaiano, J.C. (2009) Photochemical Strategies for the Facile Synthesis of Gold-Silver Alloy and Core-Shell Bimetallic Nanoparticles. Journal Of Physical Chemistry C, 113, 11861-11867.
[11] Shafaghat, A. (2015) Synthesis and characterization of silver nanoparticles by phytosynthesis method and their biological activity. Synthesis and Reactivity in Inorganic Metal-Organic and Nano-Metal Chemistry, 45, 381-387.
[12] Huang, N.M., Radiman, S., Lim, H.N., Khiew, P.S., Chiu, W.S., Lee, K.H., Syahida, A., Hashim, R. and Chia, C.H. (2009) Gamma-ray assisted synthesis of silver nanoparticles in chitosan solution and the antibacterial properties. Che- mical Engineering Journal, 155, 499-507.
[13] Darroudi, M., Zak, A.K., Muhamad, M.R., Huang, N.M. and Hakimi, M. (2012) Green synthesis of colloidal silver nanoparticles by sonochemical method. Materials Letters, 66, 117-120.
[14] Wang, H.S., Qiao, X.L., Chen, J.G., Wang, X.J. and Ding, S.Y. (2005) Mechanisms of PVP in the preparation of silver nanoparticles. Materials Chemistry and Physics, 94, 449-453.
[15] Byeon, J.H. and Kim, Y.W. (2012) A novel polyol method to synthesize colloidal silver nanoparticles by ultrasonic irradiation. Ultrasonics Sonochemistry, 19, 209-215.
[16] Jiang, L.P., Wang, A.N., Zhao, Y., Zhang, J.R. and Zhu, J.J. (2004) A novel route for the preparation of monodisperse silver nanoparticles via a pulsed sonoelectrochemical technique. Inorganic Chemistry Communications, 7, 506-509.
[17] Suslick, K.S. and Hammerton, D.A. (1986) The site of sonochemical reactions. IEEE Transactions on Ultrasonics Fer- roelectrics and Frequency Control, 33, 143-147.
[18] Salkar, R.A., Jeevanandam, P., Aruna, S.T., Koltypin, Y. and Gedanken, A. (1999) The sonochemical preparation of amorphous silver nanoparticles. Journal of Materials Chemistry, 9, 1333-1335.
[19] Thompson, L.H. and Doraiswamy, L.K. (1999) Sonochemistry: Science and engineering. Industrial & Engineering Chemistry Research, 38, 1215-1249.
[20] Lee, G.W. and Byeon, J.H. (2009) Effects of ultrasonic processing on phase transition of flame-synthesized anatase TiO2 nanoparticles. Materials Characterization, 60, 1476-1481.
[21] McNamara, W.B., Didenko, Y.T. and Suslick, K.S. (1999) Sonoluminescence temperatures during multi-bubble cavitation. Nature, 401, 772-775.
[22] Suslick, K.S., Hammerton, D.A. and Cline, R.E. (1986) The sonochemical hot-spot. Journal of the American Chemical Society, 108, 5641-5642.
[23] Alavi, M.A. and Morsali, A. (2010) Syntheses and characterization of Sr(OH)2 and SrCO3 nanostructures by ultrasonic method. Ultrasonics Sonochemistry, 17, 132-138.
[24] Soltanzadeh, N. and Morsali, A. (2010) Sonochemical synthesis of a new nano-structures bismuth(III) supramolecular compound: New precursor for the preparation of bismuth(III) oxide nano-rods and bismuth(III) iodide nano-wires. Ultrasonics Sonochemistry, 17, 139-144.
[25] Jeevanandam, P., Koltypin, Y., Palchik, O. and Gedanken, A. (2001) Synthesis of morphologically controlled lanthanum carbonate particles using ultrasound irradiation. Journal of Materials Chemistry, 11, 869-873.
[26] Mohammadi, M. and Morsali, A. (2009) Different thallium(III) oxide nano-structures from direct thermal decomposition of two thallium(I) coordination polymers. Materials Letters, 63, 2349-2351.
[27] Yin, H.B., Yamamoto, T., Wada, Y. and Yanagida, S. (2004) Large-scale and size-controlled synthesis of silver nanoparticles under microwave irradiation. Materials Chemistry and Physics, 83, 66-70.
[28] Kotlyar, A., Perkas, N., Amiryan, G., Meyer, M., Zimmermann, W. and Gedanken, A. (2007) Coating silver nanoparticles on poly(methyl methacrylate) chips and spheres via ultrasound irradiation. Journal of Applied Polymer Science, 104, 2868-2876.
[29] Vadakkekara, R., Chakraborty, M. and Parikh, P.A. (2012) Reduction of aromatic nitro compounds on colloidal hollow silver nanospheres. Colloids and Surfaces a-Physicochemical and Engineering Aspects, 399, 11-17.
[30] Madras, G. and McCoy, B.J. (2003) Temperature effects for crystal growth: A distribution kinetics ap-proach. Acta Ma- terialia, 51, 2031-2040.
[31] Lee, C.L., Syu, C.M., Chiou, H.P., Chen, C.H. and Yang, H.L. (2011) High-yield, size-controlled synthesis of silver nanoplates and their applications as methanol-tolerant electrocatalysts in oxygen reduction reaction. International Journal of Hydrogen Energy, 36, 10502-10512.
[32] Kumbhar, A.S., Kinnan, M.K. and Chumanov, G. (2005) Multipole plasmon resonances of submicron silver particles. Journal of the American Chemical Society, 127, 12444-12445.
[33] Small, J.M. and Hintelmann, H. (2007) Methylene blue derivatization then LC-MS analysis for measurement of trace levels of sulfide in aquatic samples. Analytical and Bioanalytical Chemistry, 387, 2881-2886.
[34] Ghosh, S.K., Kundu, S., Mandal, M. and Pal, T. (2002) Silver and gold nanocluster catalyzed reduction of methylene blue by arsine in a micellar medium. Langmuir, 18, 8756-8760.
[35] Gupta, N., Singh, H.P. and Sharma, R.K. (2011) Metal nanoparticles with high catalytic activity in degradation of methyl orange: An electron relay effect. Journal of Molecular Catalysis A: Chemical, 335, 248-252.
[36] Mallick, K., Witcomb, M. and Scurrell, M. (2006) Silver nanoparticle catalysed redox reaction: An electron relay effect. Materials Chemistry and Physics, 97, 283-287. http://www.cajcd.edu.cn/pub/wml.html

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