Abstract
Magnetite nanocrystal clusters are being investigated for their potential applications in catalysis, magnetic separation, and drug delivery. Controlling their size and size distribution is of paramount importance and often requires tedious trial-and-error experimentation to determine the optimal conditions necessary to synthesize clusters with the desired properties. In this work, magnetite nanocrystal clusters were prepared via a one-pot solvothermal reaction, starting from an available protocol. In order to optimize the experimental factors controlling their synthesis, response surface methodology (RSM) was used. The size of nanocrystal clusters can be varied by changing the amount of stabilizer (tribasic sodium citrate) and the solvent ratio (diethylene glycol/ethylene glycol). Tuning the experimental conditions during the optimization process is often limited to changing one factor at a time, while the experimental design allows for variation of the factors’ levels simultaneously. The efficiency of the design to achieve maximum refinement for the independent variables (stabilizer amount, diethylene glycol/ethylene glycol (DEG/EG) ratio) towards the best conditions for spherical magnetite nanocrystal clusters with desirable size (measured by scanning electron microscopy and dynamic light scattering) and narrow size distribution as responses were proven and tested. The optimization procedure based on the RSM was then used in reverse mode to determine the factors from the knowledge of the response to predict the optimal synthesis conditions required to obtain a good size and size distribution. The RSM model was validated using a plethora of statistical methods. The design can facilitate the optimization procedure by overcoming the trial-and-error process with a systematic model-guided approach.
Highlights
Recent decades have seen an increasing interest in magnetic nanoparticles because of their unique properties, which find potential applications in biomedicine, separation, and catalysis [1,2]
Magnetite nanoparticles are in a single magnetic domain while still possessing high magnetization, which makes them respond very rapidly to an external applied magnetic field
If some aggregation in solution was detected by dynamic light scattering (DLS) after the sample was kept for longer time on the bench, 0.1–0.2 mg of tribasic citrate was added after the washing steps to the sample, followed by two minutes of sonication with a horn sonicator (Dr Hielscher ultrasonic processor UP 400 s)
Summary
Recent decades have seen an increasing interest in magnetic nanoparticles because of their unique properties, which find potential applications in biomedicine, separation, and catalysis [1,2]. A similar strategy to increase their magnetic response without losing their superparamagnetic behavior is by forming clusters of pure magnetite nanocrystals in sizes ranging from 50 nm to 1 micron or even larger. Response surface methodology (RSM) was used to test the effect of experimental factors, i.e., citrate concentration and solvent ratio, on the size and polydispersity index of nanocrystal clusters. The procedure makes it possible to assess the effect of each input factor and the interactions between them on the chosen response(s) to construct a regression model and to illustrate the input factors’ impact by means of a response surface (2D, 3D, or contour line).
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