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Journal of Materials Science

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03.07.2018 | Mechanochemical Synthesis

Synthesis and properties of nanostructured GeSb₄Te₇ prepared by mechanical alloying

verfasst von: C. M. Poffo, J. C. de Lima, S. M. Souza, D. M. Trichês, Z. V. Borges, R. S. de Biasi

Erschienen in: Journal of Materials Science | Ausgabe 19/2018

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Abstract

A nanostructured GeSb₄Te₇ (GST147) phase was produced by mechanical alloying (MA), starting from a mixture with nominal GeSb₂Te₄ composition of high-purity elemental Ge, Sb and Te powders. The effect of milling on z-coordinates of Wyckoff sites 2c and 2d occupied by the Sb and Te atoms was studied using an approach combining the Rietveld method and pair distribution function analysis. The thermal stability of GST147 and the Raman active modes of GST147 were investigated. The results of photoacoustic absorption spectroscopy show that the thermal diffusivity of nanostructured GST147 produced by MA is similar that of its bulk counterpart.

Vorheriger Artikel Mechanochemical synthesis and characterization of Ni25Te75 nanocrystalline alloy

Nächster Artikel Mechanochemically driven amorphization of nanostructurized arsenicals, the case of β-As4S4

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Hsieh W, Zalden P, Wuttig M, Lindenberg A, Mao W (2013) High-pressure Raman spectroscopy of phase change materials. Appl Phys Lett 103:191908–191913CrossRef

Zhang B, Wang X, Shen Z, Li Z, Wang C, Chen Y, Zhang J, Zhang Z, Zhang S, Han X (2016) Vacancy structures and melting behavior in rock-salt GeSbTe. Sci Rep 6(25453):1–8

Matsunaga T, Yamada N (2004) Structural investigation of GeSb₂Te₄: a high-speed phase-change material. Phys Rev B 69:104111–104119CrossRef

Hen B, Layek S, Goldstein M, Shelukhin V, Shulman M, Karpovski M, Greenberg E, Sterer E, Dagan Y, Rozenberg G, Palevski A (2018) Superconductor-insulator transition in fcc GeSb₂Te₄ at elevated pressures. Phys Rev B 97:024513–024520CrossRef

Siegrist T, Jost P, Volker H, Woda M, Merkelbach P, Schlockermann C, Wuttig M (2011) Disorder-induced localization in crystalline phase-change materials. Nat Mater 10:202–208CrossRef

Zhang W, Thiess A, Zalden P, Zeller R, Dederichs P, Raty J, Wuttig M, Blügel S, Mazzarello R (2012) Role of vacancies in metal-insulator transitions of crystalline phase-change materials. Nat Mater 11:952–956CrossRef

Nukala P, Agarwal R, Qian X, Jang M, Dhara S, Kumar K, Johnson A, Li J, Agarwal R (2014) Direct observation of metal–insulator transition in single-crystalline germanium telluride nanowire memory devices prior to amorphization. Nano Lett 14(4):2201–2209CrossRef

Siegert K, Lange F, Sittner E, Volker H, Schlockermann C, Siegrist T, Wuttig M (2015) Impact of vacancy ordering on thermal transport in crystalline phase-change materials. Rep Prog Phys 78:013001–013019CrossRef

Breznay N, Volker H, Palevski A, Mazzarello R, Kapitulnik A, Wuttig M (2012) Weak antilocalization and disorder-enhanced electron interactions in annealed films of the phase-change compound GeSb₂Te₄. Phys Rev B 86:205302–205313CrossRef

10.

Zalden P, Siegert K, Rols S, Fischer H, Schlich F, Hu T, Wuttig M (2014) Specific heat of (GeTe)_x(Sb₂Te₃)_1−x phase-change materials: the impact of disorder and anharmonicity. Chem Mater 26(7):2307–2312CrossRef

11.

Loke D, Lee T, Wang W, Shi L, Zhao R, Yeo Y, Chong T, Elliott S (2012) Breaking the speed limits of phase-change memory. Science 336:1566–1569CrossRef

12.

Lencer D, Salinga M, Grabowski B, Hickel T, Neugebauer J, Wuttig M (2008) A map for phase-change materials. Nat Mater 7:972–977CrossRef

13.

Wuttig M, Yamada N (2007) Phase-change materials for rewriteable data storage. Nat Mater 6:824–832CrossRef

14.

Hegedüs J, Elliott S (2008) Microscopic origin of the fast crystallization ability of Ge–Sb–Te phase-change memory materials. Nat Mater 7:399–405CrossRef

15.

Petrov II, Imamov RM, Pinsker ZG (1968) Electron-diffraction determination of the structures of Ge₂Sb₂Te₅ and GeSb₄Te₇. Kristallografiya 13:417–421

16.

Inorganic Crystal Structure Database–ICSD (1995) Gmelin—Institute fur Anorganishe Chemie and Fachinformationszentrum FIZ

17.

de Lima JC, Borba EC, Paduani C, dos Santos VHF, Grandi TA, Rechenberg HR, Denicoló I, Elmassalami M, Barbosa AF (1996) Mechanical alloying of Fe and Zn: phase analysis and Mossbauer studies. J Alloys Compd 234:43–47CrossRef

18.

Weeber A, Bakker H (1988) Amorphization by ball milling: a review. Phys B Condens Matter 153:93–135CrossRef

19.

Mukhopadhyay D, Suryanarayana C, Froes F (1994) Extended solid solutions in Cd–Zn powders by mechanical alloying. Scr Metall Mater 30:133–137CrossRef

20.

Yavari A, Desré P, Benameur T (1992) Mechanically driven alloying of immiscible elements. Phys Rev Lett 68(14):2235–2238CrossRef

21.

de Lima JC, Silva E, Grandi TA, Sartorelli M, Silva MR, Filho AB, Sánchez DR, Baggio-Saitovitch EM (2001) X-ray diffraction, Mössbauer and magnetization studies of nanocrystalline Fe₃₃Ge₆₇ alloy prepared by mechanical alloying. Hyperfine Interact 136(1):45–56CrossRef

22.

Borges Z, Poffo CM, de Lima JC, de Souza SM, Trichês DM, Nogueira T, Manzato L, de Biasi RS (2016) Study of structural, optical and thermal properties of nanostructured SnSe₂ prepared by mechanical alloying. Mater Chem Phys 169:47–54CrossRef

23.

de Lima JC, Ferreira A, de Biasi R (2016) Modeling the amorphous structure of mechanically alloyed amorphous Ni₃₀Nb₇₀ using anomalous wide-angle X-ray scattering and reverse Monte Carlo simulations. J Non-cryst Solids 447:21–28CrossRef

24.

Rovani P, Ferreira A, Pereira A, de Lima JC (2017) Effect of pressure on nanostructured Gd₃Fe₅O₁₂. J Appl Phys 122:035904–035910CrossRef

25.

Rebelo Q, de Souza S, Trichês D, Pereira A, de Lima JC (2017) High pressure X-ray diffraction studies of the nanostructured Ge₃₄Sb₆₆ solid solution produced by mechanical alloying. J Alloys Compd 722:131–137CrossRef

26.

Souza SM, da Frota H, Trichês D, Ghosh A, Chaudhuri P, Gusmao M, Pereira A, Siqueira M, Machado K, de Lima JC (2016) Pressure-induced polymorphism in nanostructured SnSe. J Appl Cryst 49:213–221CrossRef

27.

de Lima J, Cella N, Miranda L, An Chying C, Franzan A, Leite N (1992) Photoacoustic characterization of chalcogenide glasses: thermal diffusivity of Ge_xTe_1−x. Phys Rev B 46(21):14186–14189CrossRef

28.

Ferreira A, Prates P, Poffo C, de Lima JC, de Biasi R (2017) Structural and photoacoustic study of Cr₁₁Ge₁₉ prepared by mechanical alloying. Mater Res 20(4):1072–1081CrossRef

29.

Souza SM, Trichês DM, Poffo CM, de Lima JC, Grandi TA, de Biasi RS (2011) Structural, thermal, optical, and photoacoustic study of nanocrystalline Bi₂Te₃ produced by mechanical alloying. J Appl Phys 109:013512–013520CrossRef

30.

Poffo C, de Lima J, Souza S, Trichês D, Grandi T, de Biasi R (2013) Structural, thermal, optical and photoacoustic study of nanostructured FeSb₂ prepared by mechanical alloying. Phys B 413:47–54CrossRef

31.

Gleiter H (1992) Materials with ultrafine microstructures: retrospectives and perspectives. Nanostruct Mater 1(1):1–19CrossRef

32.

de Lima JC, dos Santos VHF, Grandi TA, D’Ajello PCT, Dmitriev A (2000) Thermodynamic considerations about the formation of alloys by mechanical alloying. Phys Rev B 62(13):8871–8877CrossRef

33.

Rose JH, Smith JR, Guinea F, Ferrante J (1984) Universal features of the equation of state of metals. Phys Rev B 29(6):2963–2969CrossRef

34.

http://periodictable.com/Elements/051/data.html

35.

Mezey LZ, Giber J (1982) The surface free energies of solid chemical elements: calculation from internal free enthalpies of atomization. Jpn J Appl Phys 21:1569–1571CrossRef

36.

Rietveld H (1969) A profile refinement method for nuclear and magnetic structures. J Appl Crystallogr 2:65–71CrossRef

37.

Larson AC, von Dreele RB (1994) General structure analysis system (GSAS), Los Alamos National Laboratory Report LAUR, pp. 86–748

38.

Rodriguez-Carvajal J, Study of Micro-structural effects by powder diffraction using the program FULLPROF. http://www.cdifx.univ-rennes1.fr/fps/Microstructural_effects.pdf. Acessed 21 Dec 2017

39.

Ferreira AS, Rovani PR, de Lima JC, Pereira AS (2015) High-pressure study of Ti₅₀Ni₂₅Fe₂₅ powder produced by mechanical alloying. J Appl Phys 117:075901–075910CrossRef

40.

Borges ZV, Poffo CM, de Lima JC, Souza SM, Trichês DM, de Biasi RS (2018) Structural, thermal, optical, and photoacoustic study of mechanically alloyed nanocrystalline SnTe. Mat Res 21(4):e20171077CrossRef

41.

Syassen K (2003) Computer code DATLAB. Max Planck Institute, Stuttgart

42.

Hamilton O (1990) TAPP software version 2.2. Wade Court ES Microwave Inc

43.

Wagner CNJ (1972) In Liquid metals. Chemistry and physics. In: Beer SZ (ed). Marcel Dekker, New York, p 257

44.

de Lima JC, Raoux D, Tonnerre JM, Udron D, Morrison TI, Machado KD, Grandi TA, Campos CEM (2003) Structural study of an amorphous NiZr₂ alloy by anomalous wide-angle X-ray scattering and reverse Monte Carlo simulations. Phys Rev B 67:094210–094219CrossRef

45.

Faber TE, Ziman JM (1965) A theory of the electrical properties of liquid metals. Philos Mag 11:153–173CrossRef

46.

de Lima JC, Borges ZV, Poffo CM, Souza SM, Trichês DM, de Biasi RS (2018) Approach combining the Rietveld method and pairs distribution function analysis to study crystalline materials under high-pressure and/or temperature. https://arxiv.org/ftp/arxiv/papers/1802/1802.04648.pdf. Accessed 26 May 2018

47.

de Lima JC, Borges ZV, Poffo CM, Souza SM, Trichês DM, de Biasi RS (2018) Approach combining the Rietveld method and pairs distribution function analysis to study crystalline materials under high-pressure and/or temperature: application to rhombohedral Bi₂Te₃ phase. https://arxiv.org/abs/1803.02479. Accessed 5 May 2018

48.

de Lima JC, Borges ZV, Poffo CM, Souza SM, Trichês DM, de Biasi RS (2018) The use of the Rietveld method and pairs distribution function analysis to study the pressure dependence of the trigonal SnSe₂ and SnS₂ structure. https://arxiv.org/abs/1803.05430. Accessed 10 May 2018

49.

Mangin P (1983) In: Les Amorphes Métalliques, Ecole d’Hiver–Aussois, 13–11 janvier. Les Editions De Physique, Courtaboeuf, Les Ulis, France p. 175

50.

Sosso G, Caravati S, Bernasconi M (2009) Vibrational properties of crystalline Sb₂Te₃ from first principles. J Phys Condens Matter 21:095410CrossRef

51.

Lucazeau G (2003) Effect of pressure and temperature on Raman spectra of solids: anharmonicity. J Raman Spectrosc 34:478–496CrossRef

52.

Cho E, Yoon S, Yoon HR, Jo W (2006) Micro-Raman scattering studies of Ge–Sb–Te bulk crystals and nanoparticles. J Korean Phys Soc 48(6):1616–1619

53.

Lafuente B, Downs RT, Yang H, Stone N (2015) The power of databases: the RRUFF project. In Armbruster T, Danisi RM, De Gruyter W (eds) Highlights in mineralogical crystallography, Berlin, Germany, p 1–30. http://rruff.info/

54.

Rosencwaig A, Gersho A (1976) Theory of the photoacoustic effect with solids. J Appl Phys 47:64–69CrossRef

55.

Vargas H, Miranda L (1988) Photoacoustic and related photothermal techniques. Phys Rep 161(2):43–101CrossRef

56.

Pinto Neto A, Vargas H, Leite NF, Miranda LCM (1990) Photoacoustic characterization of semiconductors: transport properties and thermal diffusivity in GaAs and Si. Phys Rev B 41:9971–9979CrossRef

57.

Rousset G, Lepoutre F (1983) Influence of thermoelastic bending on photoacoustic experiments related to measurements of thermal diffusivity of metals. J Appl Phys 54:2383–2391CrossRef

58.

de Lima JC, Schmitt M, Souza SM, Almeida TO, Jeronimo AR, Triches DM, Grandi TA, Campos CEM (2007) Structural and thermal study of nanostructured GaSb alloy prepared by mechanical alloying. J. Alloys Compd 436:13–18CrossRef

59.

Yáñez-Limón JM, González-Hernández J, Alvarado-Gil J, Delgadillo I, Vargas H (1995) Thermal and electrical properties of the Ge:Sb: Te system by photoacoustic and Hall measurements. Phys Rev B 52:16321–16324CrossRef

60.

Lichtenecker K (1926) Die Dielektrizitätskonstante künstlicher und natürlicher Mischkörper. Phys Z 27:115–118

61.

Simpkin R (2010) Derivation of Lichtenecker’s logarithmic mixture formula from Maxwell’s equations. IEEE Trans Microw Theory Tech 58(3):545–550CrossRef

Titel: Synthesis and properties of nanostructured GeSb4Te7 prepared by mechanical alloying
verfasst von: C. M. Poffo
J. C. de Lima
S. M. Souza
D. M. Trichês
Z. V. Borges
R. S. de Biasi
Publikationsdatum: 03.07.2018
Verlag: Springer US
Erschienen in: Journal of Materials Science / Ausgabe 19/2018
Print ISSN: 0022-2461
Elektronische ISSN: 1573-4803
DOI: https://doi.org/10.1007/s10853-018-2614-8

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