Statistical approach of synthesize CoFe^sub 2^O^sub 4^ nanoparticles to optimize their characteristics using response surface methodology

Statistical approach of synthesize CoFe^sub 2^O^sub 4^ nanoparticles to optimize their characteristics using response surface methodology

The performance of magnetic nanoparticles in different applications is severely depended on their size characteristics, so the study of effective parameters on these properties can play significant roles in qualifications of nanoparticles. In present work, some important factors on size features of...

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Bibliographic Details
Published in:Journal of magnetism and magnetic materials Vol. 432; p. 362
Main Authors: Shams, S Fatemeh, Kashefi, Mehrdad, Schmitz-Antoniak, Carolin
Format: Journal Article
Language:English
Published: Amsterdam Elsevier BV 15-06-2017
Subjects:
Biomedical engineering
Cations
Chelating agents
Chelation
Citric acid
Fourier transforms
Light diffraction
Magnetic fields
Nanoparticles
Nitric acid
Optimization
Particle size distribution
Particulate composites
Photon correlation spectroscopy
Reduction
Response surface methodology
Transmission electron microscopy
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Summary:The performance of magnetic nanoparticles in different applications is severely depended on their size characteristics, so the study of effective parameters on these properties can play significant roles in qualifications of nanoparticles. In present work, some important factors on size features of CoFe2O4 superparamagnetic nanoparticles include the mixing order of synthesis components, the utilized reduction agents, stabilization process, and chelating mechanisms were investigated. Moreover, in order to optimize several influential factors such as the temperature, pH, and cation ratio of reaction, the experimental design was done by using central composite design method of response surface methodology. The simultaneous effects on the particles size and their size distribution were investigated by different methods i.e. dynamic light scattering, X-ray diffraction, Fourier transform inferred spectroscopy, vibration sample magnetometer, and transmission electron microscopy. Results demonstrated the mixing order of reduction agent to salt solution and also the employing of NH4OH as a reduction agent could cause to significant decreasing of particles size and size distribution. Furthermore, the nitric acid could stabilize and chelate nanoparticles more appropriate than citric acid. Based on the optimization results, the quadratic polynomial models were fitted on the responses which could predict their amounts, while temperature, pH, and their interactions had higher effectiveness. In addition, the optimum amounts of particle size (14 nm) and size distribution (4.61 nm) were achieved while temperature, pH, and cation ratio amounts are equal to 89.82 °C, 11, and 0.52, respectively.
ISSN:0304-8853
1873-4766