Effect of digestion time and alkali addition rate on physical properties of magnetite nanoparticles

Gnanaprakash, G. ; Philip, John ; Jayakumar, T. ; Baldev Raj, (2007) Effect of digestion time and alkali addition rate on physical properties of magnetite nanoparticles Journal of Physical Chemistry B, 111 (28). pp. 7978-7986. ISSN 1089-5647

Full text not available from this repository.

Official URL: http://pubs.acs.org/doi/abs/10.1021/jp071299b

Related URL: http://dx.doi.org/10.1021/jp071299b

Abstract

We investigate the effect of digestion time and alkali addition rate on the size and magnetic properties of precipitated magnetite nanoparticles. It is observed that the time required to complete the growth process for magnetite nanocrystals is very short (~300 s), compared to long digestion times (20-190 min) required for MnO and CdSe nanocrystals. The rapid growth of magnetite nanoparticles suggests that Oswald ripening is insignificant during the precipitation stage, due to the low solubility of the oxides and the domination of a solid-state reaction where high electron mobility between Fe2+ and Fe3+ ions drives a local cubic close-packed ordering. During the growth stage (0-300 s), the increase in the particle size is nominal (6.7-8.2 nm). The effect of alkali addition rate on particle size reveals that the nanocrystal size decreases with increasing alkali addition rate. The particle size decreases from 11 to 6.8 nm as the alkali addition rate is increased from 1 to 80 mL/s. During the size decrease, the lattice parameter decreases from 0.838 to 0.835 nm, which is attributed to an increase in the amount of Fe3+ atoms at the surface due to oxidation. As the alkali addition rate increases, the solution reaches supersaturation state rapidly leading to the formation of large number of initial nuclei at the nucleation stage, resulting in large number of particles with smaller size. When alkali addition rate is increased from 1 to 80 mL/s, the saturation magnetization of the particles decreases from 60 to 46 emu/g due to the reduced particle size.

Item Type:Article
Source:Copyright of this article belongs to American Chemical Society.
ID Code:40394
Deposited On:24 May 2011 05:05
Last Modified:24 May 2011 05:05

Repository Staff Only: item control page