Fabrication of a composite based on aluminum oxide nanofibers and nanodiamonds to construct phenol detection systems

Доклады Академии наук Pub Date : 2019-11-10 DOI:10.31857/s0869-5652489144-48

N. Ronzhin, Н О Ронжин, E. Posokhina, Е Д Посохина, E. Mikhlina, Е В Михлина, M. Simunin, М М Симунин, I. Nemtsev, Иван В. Немцев, I. Ryzhkov, Илья И. Рыжков, V. Bondar, Владимир Станиславович Бондарь

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Abstract

A composite based on aluminum oxide nanofibers (AONF) and modified nanodiamonds (MND) synthesized by explosion technique was made by mixing aqueous suspensions of components at a 5:1 weight ratio and incubating the mixture for 15 minutes at 32 C. It is assumed that the formation of a composite is provided by the difference in the zeta-potentials of the components - negative for MND and positive for AONF. Vacuum filtration of the mixture through a fluoroplastic filter (pore diameter of 0.6 m) formed discs with a diameter of 40 mm with subsequent heat treatment at 300 C to impart structural stability to the composite. Using scanning electron microscopy (SEM), it was revealed that the resulting composite has a network structure in which the MND particles are distributed over the AONF surface. It was established that MND incorporated into the composite catalyze the azo coupling reaction (phenol - 4-aminoantipyrine - H2O2) with the formation of a colored product (quinoneimine). The applicability of the composite for the multiple detection of phenol in aqueous samples is demonstrated.

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基于氧化铝纳米纤维和纳米金刚石复合材料构建苯酚检测系统的制备

采用爆炸法制备了基于氧化铝纳米纤维(AONF)和改性纳米金刚石(MND)的复合材料，将各组分的水悬浮液以5:1的质量比混合，并在32℃下孵育15分钟。假设复合材料的形成是由各组分的zeta电位的差异提供的- MND为负，AONF为正。通过氟塑料过滤器(孔径为0.6 m)真空过滤混合物，形成直径为40 mm的圆盘，随后在300℃下进行热处理，以赋予复合材料结构稳定性。通过扫描电子显微镜(SEM)发现，复合材料具有网状结构，其中MND颗粒分布在AONF表面。结果表明，复合材料中加入的MND可催化偶氮偶联反应(苯酚- 4-氨基安替比林- H2O2)，生成有色产物(醌亚胺)。证明了该复合材料对水样中苯酚多重检测的适用性。

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