5 research outputs found
Crystal Structure of Nd1.2FeO3 Oxide Material and Its Rietveld Refinement Analysis
The crystal structure of Nd1.2FeO3 oxide material synthesized by varying calcination temperatures was determined using the X-ray diffraction method. Further analysis by Rietveld refinement using software Rietica showed that all of the samples have an orthorhombic phase structure. The lattice constants of each a sample with variation of calcination temperature is a = 5.581059 ± 0.000736 Å, b = 7.758627 ± 0.000947 Å, c = 5.448341 ± 0.000665 Å; a = 5.580203 ± 0.000695 Å, b = 7.756789 ± 0.000908 Å, c = 5.447646 ± 0.000626 Å; and a = 5.580402 ± 0.000704 Å, b = 7.758957 ± 0.000919 Å, c = 5.449350 ± 0.000634 Å, respectively. The results of lattice constant were associated with the value of Goodness of Fit (GoF) is 0.9101%, 0.8726%, and 0.9303%, respectively. That has a strong indication of a qualified matching between the NdFeO3 model numbers of COD 2003124 with the current experimental results. The value of FWHM and the crystal size of Nd1.2FeO3 samples are 0.22o and 372 nm. The results showed that the variation of calcination temperature has not a significant change in the crystal size and homogeneity of the atomic crystal structure. These results are confirmed by simulation of the atomic structure using the Diamond software, the dominant peak of hkl (121)
Refinement Analysis using the Rietveld Method of Nd[1.2]Fe[1]O[3] Oxide Material Synthesized by Solid-State Reaction
Neodymium Ferrite Oxide (Nd1.2FeO3) has been successfully synthesized using solid state reaction by
varying annealing time. Structural crystallographic characteristics were obtained by X-ray diffraction. The
results of X-ray diffraction analysis showed the samples had been identified composed of NdFeO3 and Nd2-
O3 phase, with peak dominant correspond to hkl (121), FWHM value of 0.22° and estimated crystal size of
393 nm. Analysis using Rietveld methods obtained Nd1.2FeO3 oxide material has a crystal structure is orthorhombic
with space-group of PNMA. The results are comparable as was reported elsewhere that the oxide
material is useful for gas sensor application
Influence of Annealing Time Variation on Crystal Structure and Morphology of Oxide Material Nd1.2FeO3 by Solid-State Reaction Method
NdFeO3 is one of the oxide material can be detected various gases, like S/O2, CO, H2S,
etc. In this research, Nd1.2FeO3 as oxide material have been synthesized by solid-state reaction
with a variation of annealing time. Characterized by XRD shows that the samples have form
crystal perovskite structure with dominant phase and peak intensity correspond to hkl (121).
FWHM value for the dominant peak was 0.22°. The crystallite of the samples was determined
using Debye Scherer formula were 393.08, 393.10, and 393.10 nm, respectively. While the SEM
characterized showed the morphology of the samples was homogenous with grain size estimates of
0.2μm. These results indicate the variation of annealing time 1, 2, and 3 hours did not significantly
affect the crystallinity and morphology of Nd1.2FeO3 oxide material
The Effects of Calcination Temperatures on Crystal Structures and Morphologies of Nd1.2FeO3 Synthesized by Solid-State Reaction
NdFeO3 is one of the oxide alloys that can be used as a raw material for gas sensor.
The NdFeO3 have been synthesized using solid state reaction method by varying calcination
temperatures of 750oC, 850oC, and 950oC for 6 h. All of the Nd1.2FeO3 samples were
characterized using scanning electron microscope (SEM) and x-ray diffraction (XRD) to
identify their morphologies and phases. The results show that all of the samples formed major
phase is NdFeO3 and minor phase of Nd2O3 and have homogenous morphology with estimating
grain size is 0,2 μm for all samples. The value of FWHM and the crystal size of Nd1.2FeO3 was
obtained for each sample is 0.22º and 372 nm. The orthorhombic phase with a dominant peak
at hkl (121) is an indication that material has potential application as a gas senso
Influence of High Sintering Temperature Variation on Crystal Structure and Morphology of Nd1.2FeO3 Oxide Alloy Material by Solid-State Reaction Method
Nd1.2FeO3 powders type perovskite structure was prepared by a solid-state reaction
method. This research has been conducted with the recurring heating process at high
temperature. The raw material consisted of Nd2O3 (99.99 %) and Fe2O3 (99.99 %) which
characterized by XRD to confirm the phase and using SEM to identify the morphology
structure of the sample. Result characterized by XRD confirms the phase of NdFeO3 and
Nd2O3 with the formation of NdFeO3 having the orthorhombic structure (perovskite type). The
value of FWHM and the average crystal size of NdFeO3 was obtained for each sample is 0.20º
and 409 nm. While SEM studies showed the surface morphology of Nd1.2FeO3 has
homogeneous granules with grain size estimates is 0.2 μm. These results indicate that sample
Nd1.2FeO3 was a good candidate for gas sensor materials