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Journal of Materials Science

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22-09-2017 | Ceramics

Magnetic, optical, dielectric, and sintering properties of nano-crystalline BaFe_0.5Nb_0.5O₃ synthesized by a polymerization method

Authors: Roberto Köferstein, Florian Oehler, Stefan G. Ebbinghaus

Published in: Journal of Materials Science | Issue 2/2018

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Abstract

A one-pot polymerization method using citric acid and glucose for the synthesis of nano-crystalline BaFe_0.5Nb_0.5O₃ is described. Phase evolution and the development of the crystallite size during decomposition of the (Ba,Fe,Nb)-gel were examined up to 1100 °C. Calcination at 850 °C of the gel leads to a phase-pure nano-crystalline BaFe_0.5Nb_0.5O₃ powder with a crystallite size of 28 nm. The shrinkage of compacted powders starts at 900 °C. Dense ceramic bodies (relative density ≥ 90%) can be obtained either after conventional sintering above 1250 °C for 1 h or after two-step sintering at 1200 °C. Depending on the sintering regime, the ceramics have average grain sizes between 0.3 and 52 µm. The optical band gap of the nano-sized powder is 2.75(4) eV and decreases to 2.59(2) eV after sintering. Magnetic measurements of ceramics reveal a Néel temperature of about 23 K. A weak spontaneous magnetization might be due to the presence of a secondary phase not detectable by XRD. Dielectric measurements show that the permittivity values increase with decreasing frequency and rising temperature. The highest permittivity values of 10.6 × 10⁴ (RT, 1 kHz) were reached after sintering at 1350 °C for 1 h. Tan δ values of all samples show a maximum at 1–2 MHz at RT. The frequency dependence of the impedance can be well described using a single RC-circuit.

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Homes CC, Vogt T, Shapiro SM, Wakimoto S, Ramirez AP (2001) Optical response of high-dielectric-constant perovskite-related oxide. Science 293:673–676CrossRef

Chung SY, Kim ID, Kang SJ (2004) Strong nonlinear current–voltage behaviour in perovskite-derivative calcium copper titanate. Nat Mater 3:774–778CrossRef

Haertling GH (1999) Ferroelectric ceramics: history and technology. J Am Ceram Soc 82:797–818CrossRef

Ke S, Fan H, Huang H (2009) Dielectric relaxation in A₂FeNbO₆ (A = Ba, Sr, and Ca) perovskite ceramics. J Electroceram 22:252–256CrossRef

Patel PK, Yadav KL, Singh H, Yadav AK (2014) Origin of giant dielectric constant and magnetodielectric study in Ba(Fe_0.5Nb_0.5)O₃ nanoceramics. J Alloys Compd 591:224–229CrossRef

Wang Z, Chen XM, Ni L, Liu XQ (2007) Dielectric abnormities of complex perovskite Ba(Fe_1/2Nb_1/2)O₃ ceramics over broad temperature and frequency range. Appl Phys Lett 90:022904CrossRef

Ke S, Lin P, Huang H, Fan H, Zeng X (2013) Mean-Field Approach to Dielectric Relaxation in Giant Dielectric Constant Perovskite Ceramics, J Ceram 2013:795827

Bochenek D, Niemiec P, Szafraniak-Wiza I, Adamczyk M, Skulski R (2015) Preparation and dielectric properties of the lead-free BaFe_1/2Nb_1/2O₃ ceramics obtained from mechanically triggered powder. Eur Phys J B 88:277CrossRef

Kantha P, Pisitpipathsin N, Pengpat K, Rujijanagul G, Guo R, Bhalla AS (2011) Microstructure and electrical properties of BaFe_0.5Nb_0.5O₃ doped with GeO₂ (1–5 wt%). Ferroelectrics 425:27–38CrossRef

10.

Charoenthai N, Traiphol R (2011) Progress in the synthesis of Ba(Fe_0.5Nb_0.5)O₃ ceramics: a versatile co-precipitation method. J Ceram Process Res 12:191–194

11.

Raevski IP, Kuropatkina SA, Kubrin SP, Raevskaya SI, Titov VV, Sarychev DA, Malitskaya MA, Bogatin AS, Zakharchenko IN (2009) Dielectric and Mössbauer studies of high-permittivity BaFe_1/2Nb_1/2O₃ ceramics with cubic and monoclinic perovskite structures. Ferroelectrics 379:48–54CrossRef

12.

Saha S, Sinha TP (2002) Low-temperature scaling behavior of BaFe_0.5Nb_0.5O₃. Phys Rev B 65:134103CrossRef

13.

Chung CY, Chang YH, Chen GJ, Chai YL (2005) Preparation, structure and ferroelectric properties of Ba(Fe_0.5Nb_0.5)O₃ powders by sol–gel method. J Cryst Growth 284:100–107CrossRef

14.

Tezuka K, Henmi K, Hinutsa Y (2000) Magnetic susceptibilities and mössbauer spectra of perovskites A₂FeNbO₆ (A = Sr, Ba). J Solid State Chem 154:591–597CrossRef

15.

Galasso F, Darby W (1962) Ordering of the octahedrally coordinated cation position in the perovskite structure. J Phys Chem 66:131–132CrossRef

16.

Bhagat S, Prasad K (2010) Structural and impedance spectroscopy analysis of Ba(Fe_1/2Nb_1/2)O₃ ceramic. Phys Status Solidi A 207:1232–1239CrossRef

17.

Kar SK, Kumar P (2013) Permittivity and modulus spectroscopic study of BaFe_0.5Nb_0.5O₃ ceramics. Process Appl Ceram 7:181–187CrossRef

18.

Kar SK, Kumar P (2013) Structural, morphological and dielectric study of Ba(FeNb)_0.5O₃ ceramics synthesized by microwave processing technique. J Phys Chem Solids 74:1408–1413CrossRef

19.

Raevski IP, Prosandeev SA, Bogatin AS, Malitskaya MA, Jastrabik L (2003) High dielectric permittivity in AFe_1/2B_1/2O₃ nonferroelectric perovskite ceramics (A = Ba, Sr, Ca; B = Nb, Ta, Sb). J Appl Phys 93:4130–4136CrossRef

20.

Voorhoeve RJH, Trimble LE, Khattak CP (1974) Extrapolation of perovskite-like catalysts: Ba₂CoWO₆ and Ba₂FeNbO₃ in NO reduction and CO oxidation. Mater Res Bull 9:655–666CrossRef

21.

Chung WC, Pan KL, Lee HM, Chang MB (2014) Dry reforming of methane with dielectric barrier discharge and ferroelectric packed-bed reactors. Energy Fuels 28:7621–7631CrossRef

22.

Pan KL, Chung WC, Chang MB (2014) Dry reforming of CH₄ with CO₂ to generate syngas by combined plasma catalysis. IEEE Trans Plasma Sci 42:3809–3818CrossRef

23.

Rama N, Phillip JB, Opel M, Chandrasekaran K, Sankaranarayanan V, Gross R, Rao MSR (2004) Study of magnetic properties of A2B´NbO6 (A = Ba, Sr, BaSr; and B´ = Fe and Mn) double perovskites. J Appl Phys 95:7528–7530CrossRef

24.

Intatha U, Eitssayeam S, Tunkasiri T (2008) Giant dielectric behavior of BaFe_0.5Nb_0.5O₃ perovskite ceramic. Int J Mod Phys 22:4717–4723CrossRef

25.

Sun XH, Wang CC, Wang GJ, Lei CM, Li T, Mei JY, Cui YM (2012) Relationship between the dielectric properties and the conductivity of Ba₂FeNbO₆. J Electroceram 29:187–191CrossRef

26.

Battle PD, Gibb TC, Herod AJ, Kim SH, Munns PH (1995) Investigation of magnetic frustration in A2FeMO6, (A = Ca, Sr, Ba; M = Nb, Ta, Sb) by magnetometry and mossbauer spectroscopy. J Mater Chem 5:865–870CrossRef

27.

Wang Z, Wen YF, Li HJ, Fang MR, Wang C, Pu YP (2016) Excellent stability and low dielectric loss of Ba(Fe_0.5Nb_0.5)O₃ synthesized by a solution precipitation method. J Alloys Compd 656:431–438CrossRef

28.

Charoenthai N, Traiphol R, Rujijanagul G (2008) Microwave synthesis of barium iron niobate and dielectric properties. Mater Lett 62:4446–4448CrossRef

29.

Jha AK, Prasad K (2014) Green synthesis and characterization of BaFe_0.5Nb_0.5O₃ nanoparticles. J Chin Adv Mater Sci 2:294–302CrossRef

30.

Program WinXPOW v2.11, Stoe & Cie GmbH, Darmstadt, 2004

31.

Rodriguez-Carvajal J (1993) Recent advances in magnetic structure determination neutron powder diffraction. Phys B 192:55–69CrossRef

32.

Köferstein R (2014) Synthesis, phase evolution and properties of phase-pure nanocrystalline BiFeO₃ prepared by a starch-based combustion method. J Alloys Compd 590:324–330CrossRef

33.

Deshpande K, Mukasyan A, Varma A (2004) Direct synthesis of iron oxide nanopowders by the combustion approach: reaction mechanism and properties. Chem Mater 16:4896–4904CrossRef

34.

Hirata Y, Hara A, Aksay IA (2009) Thermodynamics of densification of powder compact. Ceram Int 35:2667–2674CrossRef

35.

Köferstein R, Walther T, Hesse D, Ebbinghaus SG (2013) Preparation and characterization of nanosized magnesium ferrite powders by a starch-gel process and corresponding ceramics. J Mater Sci 48:6509–6518. doi:10.1007/s10853-013-7447-x CrossRef

36.

Eitssayeam S, Intatha U, Pengpat K, Tunkasiri T (2006) Preparation and characterization of barium iron niobate (BaFe_0.5Nb_0.5O₃) ceramics. Curr Appl Phys 6:316–318CrossRef

37.

Mendelson MI (1969) Average grain size in polycrystalline ceramics. J Am Ceram Soc 52:443–446CrossRef

38.

Kubelka P, Munk F (1931) Ein beitrag zur optik der farbanstriche. Z Techn Phys 11:593–601

39.

Kortüm G, Vogel J (1958) Die Theorie der diffusen Reflexion von Licht an pulverförmigen Stoffen. Z Phys Chem 18:110–122CrossRef

40.

Patel PK, Yadav KL, Kaur G (2014) Reduced dielectric loss in Ba_0.95Sr_0.05(Fe_0.5Nb_0.5)O₃ thin film grown by pulsed laser deposition. RSC Adv 4:28056–28061CrossRef

41.

Köferstein R, Buttlar T, Ebbinghaus SG (2014) Investigations on Bi₂₅FeO₄₀ powders synthesized by hydrothermal and combustion-like processes. J Solid State Chem 217:50–56CrossRef

42.

Kar SK, Swain S, Kumar P (2015) High dielectric constant and low optical band gap studies of La-modified Ba(Fe_0.5Nb_0.5)O₃ ceramics. Mater Chem Phys 155:171–177CrossRef

43.

Yu J, Tang S, Zhai L, Shi Y, Du Y (2009) Synthesis and magnetic properties of single-crystalline BaFe₁₂O₁₉ nanoparticles. Phys B 404:4253–4256CrossRef

44.

Shafie MSE, Hashim M, Ismail I, Kanagesan S, Fadzidah MI, Idza IR, Hajalilou A, Sabbaghizadeh R (2014) Magnetic M-H loops family characteristics in the microstructure evolution of BaFe12O19. J Mater Sci Mater Electron 25:3787–3794CrossRef

45.

Raevski IP, Titov VV, Malitskaya MA, Eremin EV, Kubrin SP, Blazhevich AV, Chen H, Chou CC, Raevskaya SI, Zakharchenko IN, Sarychev DA, Shevtsova SI (2014) Studies of ferroelectric and magnetic phase transitions in multiferroic PbFe_0.5Ta_0.5O₃–PbTiO₃ solid solution ceramics. J Mater Sci 49:6459–6466. doi:10.1080/00150193.2015.995009 CrossRef

46.

Puri M, Bahel S, Raevski IP, Narang SB (2016) Structural, dielectric and magnetic properties of (Pb_1-xCa_x)(Fe_0.5Nb_0.5)O₃ solid solution ceramics. J Magnet Magnet Mater 407:195–200CrossRef

47.

Amonpattaratkit P, Jantaratana P, Ananta S (2015) Influences of PZT addition on phase formation and magnetic properties of perovskite Pb(Fe_0.5Nb_0.5)O₃-based ceramics. J Magnet Magnet Mater 389:95–100CrossRef

48.

Intatha U, Eitssayeam S, Pengpat K, MacKenzie KJD, Tunkasiri T (2007) Dielectric properties of low temperature sintered LiF doped BaFe_0.5Nb_0.5O₃. Mater Lett 61:196–200CrossRef

49.

Oehler F, Langhammer HT, Ebbinghaus SG (2017) Preparation and dielectric properties of CaTaO₂N and SrNbO₂N ceramics. J Eur Ceram Soc 37:2129–2136CrossRef

Title: Magnetic, optical, dielectric, and sintering properties of nano-crystalline BaFe0.5Nb0.5O3 synthesized by a polymerization method
Authors: Roberto Köferstein
Florian Oehler
Stefan G. Ebbinghaus
Publication date: 22-09-2017
Publisher: Springer US
Published in: Journal of Materials Science / Issue 2/2018
Print ISSN: 0022-2461
Electronic ISSN: 1573-4803
DOI: https://doi.org/10.1007/s10853-017-1609-1

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