Phase transitions in TbMnO3 manganites

Dyakonov, V. P.; Szytuła, A.; Szymczak, R.; Zubov, E.; Szewczyk, A.; Kravchenko, Z.; Bażela, W.; Dyakonov, K.; Zarzycki, A.; Varyukhin, V. N.; Szymczak, H.

doi:10.1063/1.3691530

Cited by 17 publications

(8 citation statements)

References 19 publications

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“…The analysis of the diffractograms obtained for the different nano-samples indicates that the fitted structural parameters differ slightly on those for the bulk samples. The data from the X-ray diffraction measurements are listed in Table 1 in [3] and Table 1 in [4].These data confirm that the nano-samples have the similar crystal structure that bulk one. The unit cell volume values reported for the nanoparticle samples are slightly less (about of 1 %) than the value for bulk materials (see Table 23.1).…”

Section: Crystal Structuresupporting

confidence: 78%

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Magnetic Properties of Nanoparticle RMnO3 (R=Pr, Nd, and Tb) Compounds

Bażela

Szytuła

Baran

et al. 2014

Springer Proceedings in Physics

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The manganese perovskites with the general formula AMnO 3 , where A = La, a rare earth metal or Ca, Sr, etc., are subject of intensive investigations of their magnetic and electric properties. Structural and magnetic properties of these compounds are sensitive to both the manganese valence and internal (chemical) factors. The interest in the manganite has been renewed with the discovery of colossal magnetoresistance, magnetocaloric response, and multiferroic behavior. Recently, the investigations concentrate on the influence of the grain size on their properties. The model for an interpretation of the magnetic properties of the nanoparticle compounds is based on the ratio of ideal inner core and nonmagnetic surface, i.e., on the surface/volume ratio [1].For RMnO 3 (R = rare earth elements) compounds, the critical temperature of the magnetic ordering, which indicates change of magnetic interactions, decreases with increasing number of 4 f electrons (see Fig. 1 in [2]).

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Section: Crystal Structuresupporting

confidence: 78%

“…The investigated nanoparticle compounds were obtained by a sol-gel technique described in [3,4]. The obtained products were annealed at different temperatures between 800 and 900…”

Section: Methodsmentioning

confidence: 99%

Magnetic Properties of Nanoparticle RMnO3 (R=Pr, Nd, and Tb) Compounds

Bażela

Szytuła

Baran

et al. 2014

Springer Proceedings in Physics

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“…No anomalies related to the magnetic ordering of Mn 3þ moments (as reported for TMO single crystals 9 ) are observed, which is consistent with previous reports for other bulk TMO and is thought to be due to the paramagnetic ordering of larger Tb 3þ moments dominating the AFMordered Mn moments. 25,26 The temperature and frequency dependent real (v 0 ) and complex (v 00 ) parts of the ac susceptibility for the TMO sample are plotted in Figure 2 features to those seen in v dc were observed in the ac susceptibility data. TMO sample exhibits a frequency dependent peak at the Tb 3þ ordering temperature in the v 0 (T) data, and no other significant anomalies are observed.…”

mentioning

confidence: 90%

Effects of holmium substitution on multiferroic properties in Tb0.67Ho0.33MnO3

Staruch

Lawes

Kumarasiri

et al. 2013

Applied Physics Letters

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In this work, the structural, electrical, and magnetic properties of orthorhombic TbMnO3 and Tb0.67Ho0.33MnO3 ceramics are presented. The lattice parameters and the Mn-O-Mn bond angle were found to decrease with Ho-substitution as evidenced by Rietveld refinement of the X-ray diffraction data and Raman spectroscopy measurements. A weak ferromagnetic moment was observed in both dc and ac magnetic measurements of the Ho-substituted sample possibly due to spin canting in the antiferromagnetic phase. Tb0.67Ho0.33MnO3 was confirmed to be multiferroic with appearance of spontaneous polarization below 25 K and an additional increase in polarization ∼15.5 K associated with the ordering of the Ho3+ moments.

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“…With a decrease of temperature, there exists an increase in magnetization at 65 K due to the appearance of weak ferromagnetism, which may be contributed by the canting of Mn moments and the polarization of the Gd spins. In the present nano particles, complex magnetic transitions could take place in the vicinity of the transition temperatures of GdMnO 3 , corresponding to the sine wave ordering of Mn 3+ moments and magnetic ordering of Gd 3+ moments, respectively [36]. The Complex magnetic transition of GdMnO 3 nano particles verified by the hysteresis loops of GdMnO 3 nano-particles recorded at different temperatures 20 K, 40 K, 60 K, 80 K and 100 K respectively as shown in Fig.…”

Section: Downloaded By [University Of Saskatchewan Library] At 00:01 mentioning

confidence: 96%

Thermal, Magnetic and Electrical Properties of Multiferroic GdMnO₃Nano Particles by a Co-Precipitation Method

Prakash

Kumar

Buddhudu

2012

Ferroelectrics Letters Section

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In the present work, GdMnO 3 multiferroic materials have been synthesized by a conventional chemical co-precipitation method to study their thermal, structural, magnetic and electrical properties of multiferroic GdMnO 3 nano particles. These materials have been sintered at different temperatures of 700 • C, 800 • C, 900 • C, 1000 • C and 1100 • C respectively in order to evaluate their optimum sintering temperature based on XRD profiles. These materials are found to be in orthorhombic crystal structure (JCPDS Card No: 250337) and their lattice parameters are a = 5.310Å, b = 5.840Å and c = 7.430 Å. The morphology of the GdMnO 3 nano particles has been examined from the measurement of HRSEM images with the changes in sintering temperatures. Elemental analysis of host matrix has been confirmed from the EDAX profile. Functional groups of GdMnO 3 have also been analyzed from their FTIR spectral. Thermal analysis of the as synthesized chemicals combination has been carried out from the measurement of its TG-DTA features and these results have been correlated with XRD profiles. For these materials, dielectric properties ((ε and ε ) ac conductivity (σ ac ) and dc conductivity) in the range of 100 Hz -1 MHz at the room temperature have also been investigated. The zero-field-cooled (ZFC) and field-cooled (FC) magnetizations could reveal that complex magnetic transitions would occur in a temperature range from 20 to 200 K (keeping the field constant at H = 500 Oe) confirming these trends in the forms magnetic hysteresis loops in evaluating their potential uses in different multiferroic applications.

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Phase transitions in TbMnO3 manganites

Cited by 17 publications

References 19 publications

Magnetic Properties of Nanoparticle RMnO3 (R=Pr, Nd, and Tb) Compounds

Magnetic Properties of Nanoparticle RMnO3 (R=Pr, Nd, and Tb) Compounds

Effects of holmium substitution on multiferroic properties in Tb0.67Ho0.33MnO3

Thermal, Magnetic and Electrical Properties of Multiferroic GdMnO₃Nano Particles by a Co-Precipitation Method

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Phase transitions in TbMnO3 manganites

Cited by 17 publications

References 19 publications

Magnetic Properties of Nanoparticle RMnO3 (R=Pr, Nd, and Tb) Compounds

Magnetic Properties of Nanoparticle RMnO3 (R=Pr, Nd, and Tb) Compounds

Effects of holmium substitution on multiferroic properties in Tb0.67Ho0.33MnO3

Thermal, Magnetic and Electrical Properties of Multiferroic GdMnO3Nano Particles by a Co-Precipitation Method

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Thermal, Magnetic and Electrical Properties of Multiferroic GdMnO₃Nano Particles by a Co-Precipitation Method