(2) By increasing the nanoparticle size at a fixed concentration,

(2) By increasing the nanoparticle size at a fixed concentration, the increased proximity of surface atoms from adjacent nanoparticles results in inter-particle exchange interactions, leading to the formation of a collective state which in the case of randomly distributed nanoparticles is very similar to a spin glass [35]. Therefore, the net magnetic moment of the agglomerate will decrease,

and the applied field of 20 mT would not be sufficient to suspend VX-689 cost the aggregation; therefore, the precipitation occurs. Table  3 shows the susceptibility of magnetic fluids of various nanoparticle sizes at 32 mg/ml concentration. Table 3 Magnetic susceptibility of prepared fluids

with various nanoparticle sizes at 32 mg/ml concentration Nanoparticle mean size (nm) Susceptibility (χ) × 10-5 1.5 1.46 2.5 3.94 4 6.73 5.5 10.74 Effect of magnetic fluid concentration To study the effect of nanoparticle concentration on the stability of magnetic fluids, W4 nanoparticles which have the largest mean size among all samples were used to prepare magnetic fluids with different concentrations. Figure  8b shows the change of magnetic weight with time; for 32, AZD0530 nmr 30, and 28 mg/ml, the magnetic weight reduces to 0.006, 0.006, and 0.005 gr, respectively. It is seen that the higher the concentration of nanoparticles, the this website greater the decrease of magnetic weight. In fact, at higher concentrations, nanoparticles are in lower spatial distances, and therefore,

the probability of precipitation is higher based on the mechanisms described in the previous section. Also, the effect of dilution was investigated at the ratio of 1:5 by reducing the nanoparticle concentration from 32 to 6.4 mg/ml. It is seen that the magnetic fluid is stable even after being diluted since Bortezomib molecular weight the reduction of magnetic weight is about 0.002 gr. This is in line with the results reported by Hong et al. on the stability of Fe3O4 nanofluids [16]. As they reported for magnetite nanoparticles, the reason is that the surfactant bilayer could not be destroyed when the magnetic fluid is diluted. SAR measurements Figure  9a shows the evolution of temperature for magnetic fluids containing W1 to W4 nanoparticles after switching on the magnetic field at fixed values of H = 20 kA m-1 and f = 120 kHz.

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