The mineral composition and magnetic behavior of nano-Fe2O3 of iron ore from Lhoong mining area, Aceh province, were studied. The iron ore was prepared by mechanical milling method. The mineral and chemical compositions of samples were investigated by XRD and XRF analysis tests. The XRF test showed that the Lhoong iron ore contains Fe2O3 (93.88%) in association with other isomorphous impurities, such as SiO2, MnO, and Al2O3, in varying proportions. Compared to XRD results, it was consistent with XRF; the phase compositions of iron ore were mainly hematite (Fe2O3). The XRD revealed that hematite was the major mineral component in the Lhoong iron ores. SEM observation showed fine crystalline structure of Lhoong iron ore after the milling process. The main mineral morphology was microcrystalline in agglomerate forms. The magnetic properties of the samples after milling showed the increasing in the remanent (
Nowadays, iron oxide plays a crucial role in various applications and is intensively investigated, especially for its application in magnetic materials [
Interestingly, iron oxide can be obtained from natural iron ore (e.g., from mineral rock, beach sand, etc.). Indonesia, which is rich in iron ore, should strive for self-sufficiency in meeting the needs of the industry, such as iron-steel industry. One of the areas known as the largest deposits of iron ore is the Aceh province.
In this paper we provide a qualitative data that includes the identification phase, the percentage of mineral, morphology, and the magnetic properties of the iron ore in Lhoong, Aceh Besar. Iron ore reserves in Aceh are spread in several areas such as Aceh Besar, Pidie, Aceh Barat Daya, Aceh Selatan, Subulussalam, Gayo Lues, and Aceh Timur with total deposits exceeding 92.3 million tonnes [
The iron ore samples were collected from the strip mine in Lhoong area, Aceh Besar district, Aceh Province, Indonesia. The iron ores are irregularly scattered in the ore body layer, making them show an even chemical distribution; therefore, this research randomly collected samples in each ferralitic soil profile. The iron ore rock was firstly crushed by a disc-mill in 30 minutes to produce powders. Then, for advanced milling, the powders were filled into a hardened steel vial and sealed together with 10 balls (5.6 mm in diameter). The mixture powders were milled in a home-made planetary ball mill (PBM) at a rotational speed of 300 rpm (ball to powder ratio 10 : 1) for 20 hours. Structural changes during milling were characterised by XRD (Philips PW 7310, Co-K
Figure
XRD profile of Lhoong iron ore after 20 hours milling.
As a result, by using a planetary ball mill (PBM) for 20 hours, effectively managed to form a fine powder sample which is believed to have a crystal size on the nanometer scale. Based on XRD observations, there has been peak broadening phenomenon. Using Scherrer formula [
Furthermore, the observation of microstructure using SEM as shown in Figure
SEM image of Lhoong iron ore before (a) and after 20 hours milling (b).
As shown, particle size of less than 5 mm indicates that the particle is polycrystalline fine particle (fine polycrystal). It can be mentioned that, the milling process of 20 hours obtain by high energy ball mill affects the grain size reduction of natural Fe2O3 powder. This result also shows that mechanical alloying (MA) method is very attractive and promising in the preparation of nanoscale materials from iron ore.
Then, the X-ray fluorescence (XRF) test and the results for elements percentage are summarized in Table
Chemical composition of Lhoong iron ore.
No. | Formula | Concentration (%) |
---|---|---|
1 | Fe2O3 | 93.88 |
2 | SiO2 | 3.43 |
3 | MnO | 0.55 |
4 | Al2O3 | 0.43 |
5 | K2O | 0.38 |
6 | P2O5 | 0.33 |
7 | SO3 | 0.29 |
8 | Nd2O3 | 0.27 |
| ||
Total | 99.56 |
As shown, the XRF results are consistent with the XRD data, where the main element is iron oxide of hematite Fe2O3 (93.88 wt%). Besides hematite, some other elements were detected but with a small percentage, for example, silica SiO2 at 3.43 wt%, MnO (0.55 wt%), Al2O3 (0.43 wt%), and several others.
The process of further milling the sample using a planetary ball mill for 20 hours has shown that the size of the crystals on the nanometer scale affects magnetic properties. As shown in Figure
Hysteresis loop of Lhoong sample before milling.
Hysteresis loop of Lhoong sample after 20 h milling.
From the magnetic properties test, the samples after milling show that there has been an increase in the value of remanent magnetization properties (
From the initial identification of Lhoong iron ore using both techniques of X-ray diffraction (XRD) and X-ray fluorescence (XRF), showed that the Fe2O3 appeared as the major phase and has a chemical composition of 93.88 wt%. The surface microstructure which was investigated with scanning electron microscope (SEM) informed that the elements of the iron oxide hematite Fe2O3 are very dominant. Accordingly, the process of milling iron ore grains also showed that the material can be modified into nanostructured materials, as shown by the peak broadening in XRD patterns and correlated well with the observation of the surface morphology by electron microscopy. The magnetic properties of the samples after milling showed that there has been an increase in the remanent (
The authors gratefully recognize the financial support provided by the Directorate General of Higher Education, Indonesian Ministry of Education and Culture, through the MP3EI project (Contract no. 217/SP2H/PL/Dit.Litabmas/V/2012). The fruitful discussion of Dr. Erfan Handoko (UNJ, Jakarta) and the use of Permagraph facilities at the RCMS (UI, Jakarta) are acknowledged.