Production of Mn3O4 nanoparticles from a manganiferous iron ore via reductive leaching, precipitation, and calcination
Abstract
The synthesis of Mn3O4 nanoparticles from a manganiferous iron ore through reductive leaching, precipitation,
and calcination was investigated. The reductive leaching results showed that Mn (99.9%) was almost completely
extracted into the leaching solution along with a substantial amount of Mg (99.9%), Al (99.5%), Ca (80%), and
Fe (22.9%) under the following conditions: 30 g/L tartaric acid as a reducing agent, 1 M HCl solution, leaching
temperature of 90 ◦C, and leaching duration of 3 h. In the first precipitation step, Fe and Al were expelled from
the pregnant leach solution by the addition of NaOH prior to conducting the precipitation experiments for the
production of manganese carbonate (MnCO3) particles from the purified solution. In the second precipitation
step, MnCO3 particles were produced using sodium carbonate (Na2CO3) as the precipitating agent. The effects of
parameters such as reaction temperature, Na2CO3 concentration, and experimental duration were investigated
using the Taguchi approach. Manganse(II) was precipitated in the form of MnCO3 particles (97.4%) under the
following conditions: a temperature of 30 ◦C, Na2CO3 concentration of 0.014 mol/L, and duration of 30 min. The
precipitate was observed to have a structure similar to that of rhodochrosite (MnCO3). Thermogravimetric/
differential thermal analyses were subsequently performed in three different atmospheres (air, oxygen, and nitrogen) to select a suitable atmosphere for calcination. The experimental results indicated the formation of
hausmannite (Mn3O4) with a purity of 97.5% Mn3O4, 0.42% MgO, 1.66% CaO, and 0.34% FeO. The specific
surface area, particle size, Curie temperature, magnetisation, coercivity, and remanence ratio of the final product
obtained via 3 h of calcination at 350 ◦C were estimated to be 133.3 m2
/g, <142.2 nm, 56 K, 10.10 Am2
/kg,
0.35 T, and 0.19, respectively. The characterisation results revealed the excellent low-temperature ferromagnetic
properties of the produced Mn3O4 nanoparticles.