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Journal of Nanoparticle Research

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01-10-2011 | Research Paper

Structural and Mössbauer studies of aerosol FeCu nanoparticles in a wide composition range

Authors: E. A. Shafranovsky, Yu. I. Petrov, Ll. Casas, E. Molins

Published in: Journal of Nanoparticle Research | Issue 10/2011

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Abstract

Structure and magnetic state of aerosol FeCu nanoparticles of 10–30 nm size with Cu content of 0.6–92.1 at.% have been examined by X-ray diffraction and Mössbauer spectroscopy. The FeCu particles have been shown to consist of an iron core surrounded by a copper and Fe oxide shell. With increasing Cu content the iron core having a bcc structure is reduced down to its complete disappearance followed by vanishing ferromagnetism of the particles. Within the copper content from 4.9 to 74.3 at.% the bcc and fcc phases coexist, with the fcc phase having a lattice constant close to that of pure copper and the bcc lattice constant being slightly higher than that for pure Fe due to embedding Cu atoms into the Fe lattice. At Fe-rich FeCu samples a presence of two-spin (ferromagnetic and paramagnetic) components of the fcc Fe is also observed. In the case of a thin copper shell there is only the ferromagnetic fcc Fe, whereas with further thickening of the shell both spin states of the fcc Fe appear existing up to a 20% Cu content. For FeCu samples with a higher Cu content they disappear due to oxidation of the copper grains. The Cu-rich samples with Cu content higher 80 at.% have a fcc structure, with the lattice constant being slightly higher than that of copper and they are paramagnetic. A slight increase of the lattice constant is due to the penetration of small iron aggregations into the Cu grains. In contact with air, the FeCu particles become covered with Fe₃O₄ and Cu₂O. Their long-term exposure to ambient conditions leads to further oxidation process of Cu₂O to CuO.

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Abrahams SC, Guttman L, Kasper JS (1962) Neutron diffraction determination of antiferromagnetism in face-centered cubic (γ) iron. Phys Rev 127:2052–2055CrossRef

Bakkaloğlu ÖF (1998) A magnetic study of sputtered Fe/Cu multilayer films. J Magn Magn Mater 182:324–328CrossRef

Baldokhin YV, Petrov YI (1992) Two states of the face-centered-cubic structure in iron discovered while investigating the Mössbauer spectra and the thermal expansion of small particles. Sov Phys Dokl 37:563–565

Bandyopadhyay B, Pahari B, Ghoshray K (2007) Magnetization and ⁶³Cu NMR studies on granular FeCu alloys. Phys Rev B 76:214424CrossRef

Barro MJ, Navarro E, Agudo P, Hernando A, Crespo P, Garsía-Escorial A (1997) Structural evolution during milling of diluted solid solutions of Fe–Cu. Mater Sci Forum 235–238:553–558CrossRef

Brand RA (1987) Improving the validity of hyperfine field distributions from magnetic alloys. Part 1: Unpolarized source. Nucl Instrum Methods Phys Res B 28:398–416CrossRef

Chien CL, Liou SH, Kofalt D, Yu W, Egami T, McGuire TR (1986) Magnetic properties of Fe_xCu_100−x solid solutions. Phys Rev B 33:3247–3250CrossRef

Chubing P, Daosheng D (1994) Magnetic properties and magnetoresistance in granular Fe–Cu alloys. J Appl Phys 76:2986–2990CrossRef

Chubing P, Haiying C, Guozhong L, Daosheng D (1994) Magnetic properties of Fe_xCu_1−x granular alloy films. J Appl Phys 76:7102–7104CrossRef

Crespo P, Hernando A, Yavari R, Drbohlav O, García-Escorial A, Barandiaran JM, Orúe I (1993) Magnetic behavior of metastable fcc Fe–Cu after thermal treatments. Phys Rev B 48:7134–7139CrossRef

Crespo P, Hernando A, Garcia-Escorial A, Kemner KM, Harris VG (1994) Extended X-ray-absorption fine-structure studies of heat-treated fcc-Fe₅₀Cu₅₀ powders processed via high-energy ball milling. J Appl Phys 76:6322–6324CrossRef

Crespo P, Menéndes N, Tornero JD, Barro MJ, Barandiarán JM, Garsía-Escorial A, Hernando A (1998) Mössbauer spectroscopy evidence of a spinodal mechanism for the thermal decomposition of fcc FeCu. Acta Mater 46:4161–4166CrossRef

da Costa GM, De Grave E, Vandenberghe RE (1998) Mössbauer studies of magnetite and Al-substituted maghemites. Hyperfine Interact 117:207–243CrossRef

Del Bianco L, Ballesteros C, Rojo JM, Hernando A (1998) Magnetically ordered fcc structure at the relaxed grain boundaries of pure nanocrystalline Fe. Phys Rev Lett 81:4500–4503CrossRef

Donath M, Pickel M, Schmidt AB, Weinelt M (2009) Ferromagnetic Fe on Cu(001) throughout the fcc-like phase: arguing from the viewpoint of the electronic structure. J Phys 21:134004

Duc NH, Tuan NA, Fnidiki A, Dorien C, Teillet J, Ben Youssef J, Le Gall H (2002) Structural, magnetic and Mössbauer studies of Fe–Cu granular films. J Phys 14:6657–6666

Enzo S, Mulas G, Frattini R, Principi G, Gupta R, Cooper R, Cowlam N (1997a) A study of mechanically alloyed Cu₇₀Fe₃₀ by diffraction, spectroscopy and DSC. Mater Sci Forum 235–238:529–534CrossRef

Enzo S, Mulas G, Frattini R, Cooper RJ, Cowlam N, Principi G (1997b) A study of phase separation in metastable Cu₅₀Fe₅₀ alloys by neutron diffraction and neutron small-angle scattering. Philos Mag B 76:471–482

Escorial AG, Filho WB, Drbohlav O, Cresco P, Urchulutegui M, Antisari MV, Hernando A, Yavari AR (1997) Contrast modulation during decomposition of supersaturated fcc Fe–Cu solid and liquid solutions. Mater Sci Forum 235–238:559–564CrossRef

Gonser U, Meechan CJ, Muir AH, Wiedersich H (1963) Determination of Néel temperatures in fcc iron. J Appl Phys 34:2373–2378CrossRef

Gorria P, Martinez-Blanco D, Blanco JA, Hernando A, Garitaonandia JS, Barquin LF, Campo J, Smith RI (2004) Invar effect in fcc-FeCu solid solutions. Phys Rev B 69:214421CrossRef

Gorria P, Martinez-Blanco D, Blanco JA, Perez MJ, Hernando A, Barquin LF, Smith RI (2005) High-temperature induced ferromagnetism on γ-Fe precipitates in FeCu solid solutions. Phys Rev B 72:014401CrossRef

Gradmann U, Isbert HO (1980) Ferromagnetic γ-iron films prepared on CuAu(111)-surfaces. J Magn Magn Mater 15–18:1109–1111CrossRef

Guen MY, Petrov YI (1969) Dispersnye kondensaty metallicheskogo para (Dispersed metal vapor condensates). Uspekhi Khimii (Adv Chem) 38:2249–2278 (in Russian)

Guen MY, Ziskin MS, Petrov YI (1959) Issledovanie dispersnosti aerosolej alyuminiya v zavisimosti ot usloviy ikh obrazovaniya (Study of dispersion of Al aerosols depending on the conditions of their formation). Dokl Akad Nauk SSSR 127:366–368 (in Russian)

Guigue-Millot N, Keller N, Perriat P (2001) Evidence for the Verwey transition in highly nonstoichiometrie nanometric Fe-based ferrites. Phys Rev B 64:012402CrossRef

Guo H, Ma X, Yang L, Shen B, Zhao J (1991) Structure, magnetic properties and stability of the interfaces in Fe/Cu multilayer. J Magn Magn Mater 99:199–203CrossRef

Halbauer R, Gonser U (1983) Antiferromagnetism of fcc iron films. J Magn Magn Mater 35:55–56CrossRef

Hernando A, Crespo P, Yavari AR, García-Escorial A, Barandiaran JM (1993a) Formation of γ-Fe by mechanical alloying of Cu–Fe? IEEE Trans Magn 29:2634–2636CrossRef

Hernando A, Crespo P, García-Escorial A, Barandiaran JM (1993b) Comment on “Mechanically driven alloying of immiscible elements”. Phys Rev Lett 70:3521–3522CrossRef

Hornstein F, Ron M (1974) Plastic deformation of a Cu-1.92 w/o Fe alloy. J Phys 35:C6-497–C6-500

Jiang JZ, Gonser U, Gente C, Borman R (1993) Thermal stability of the unstable fcc-Fe₅₀Cu₅₀ phase prepared by mechanical alloying. Appl Phys Lett 63:1056–1058CrossRef

Jiang JZ, Pankhurst QA, Johnson CE, Gente C, Bormann R (1994) Magnetic properties of mechanically alloyed FeCu. J Phys 6:L227–L232

Jiang JZ, Gente C, Bormann R (1998) Mechanical alloying in the Fe–Cu system. Mater Sci Eng A 242:268–277CrossRef

Johanson GJ, McGirr MB, Wheeler DA (1970) Determination of the Néel temperature of face-centered-cubic iron. Phys Rev B 1:3208CrossRef

Kaloshkin SD, Tomilin IA, Andrianov GA, Baldokhin YV, Shelekhov EV (1997) Phase transformations and hyperfine interactions in mechanically alloyed Fe–Cu solid solutions. Mater Sci Forum 235–238:565–570CrossRef

Kaufmann L, Clougherty EV, Weiss RJ (1963) The lattice stability of metals-III. Iron. Acta Metall 11:323–335CrossRef

Keune W, Lauer J, Williamson DL (1974) Mössbauer studies of FeCu thin films. J Phys 35:C6-473–C6-476

Keune W, Halbauer R, Gonser U, Lauer J, Williamson DL (1977) Antiferromagnetism of fcc Fe thin films. J Appl Phys 48:2976–2979CrossRef

Keune W, Ezawa T, Macedo WAA, Glos U, Schletz KP, Kirschbaum U (1989) Magneto-volume effects in γ-Fe ultrathin films and small particles. Physica B 161:269–275CrossRef

Klein J, Heck T, Campbell SJ, Aubertin F, Gonser U (1990) The activation energy for γ-Fe precipitates in CuFe. Hyperfine Interact 54:811–816CrossRef

Kneller EF (1964) Magnetic and structural properties of metastable Fe-Cu solid solutions. J Appl Phys 35:2210–2211CrossRef

Kuhrt C, Schultz L (1993) Magnetic properties of nanocrystalline mechanically alloyed Fe–M (M = Al, Si, Cu). IEEE Trans Magn 29:2667–2669CrossRef

Lanotte L, Matteazzi P (1991) Magnetic behaviour of Fe_1−xCu_x powders after milling. J Magn Magn Mater 101:178–180CrossRef

Lutterrotti L, Gialanella S (1997) X-ray diffraction characterization of heavily deformed metallic specimens. Acta Mater 46:101–110CrossRef

Macedo WAA, Keune W (1988) Magnetism of epitaxial fcc-Fe(100) films on Cu(100) investigated in situ by conversion-electron Mössbauer spectroscopy in ultrahigh vacuum. Phys Rev Lett 61:475–478CrossRef

Macri PP, Rose P, Frattini R, Enzo S, Principi G, Hu WX, Cowlam N (1994a) A study of Fe₅₀Cu₅₀ produced by mechanical alloying and its thermal treatment. J Appl Phys 76:4061–4067CrossRef

Macri PP, Enzo S, Cowlam N, Frattini R, Principi G, Hu WX (1994b) Mechanical alloying of immiscible Cu₇₀TM₃₀ alloys (TM = Fe, Co). Philos Mag B 71:249–259

Martinez B, Roig A, Obradors X, Molins E, Rouanet A, Monty C (1996) Magnetic properties of γ-Fe₂O₃ nanoparticles obtained by vaporization condensation in a solar furnace. J Appl Phys 79:2580–2586CrossRef

Matsui M, Chikazumi S (1978) Analysis of anomalous thermal expansion coefficient of Fe–Ni Invar alloys. J Phys Soc Jpn 45:458–465CrossRef

Norton JT (1935) Solubility of copper in iron, and lattice changes during aging. Trans Am Inst Min Metall Eng 116:386–396

Özdemir Ö, Dunlop DJ, Moscowitz BM (1993) The effect of oxidation on the Verwey transition in magnetite. Geophys Res Lett 20:1671–1674CrossRef

Pankhurst QA, Thomas MF, Johnson CE, Zquiak R, Zhang XX, Tejada J (1994) A Mössbauer study of Fe(5 Å) + Cu(50 Å) multilayers. IEEE Trans Magn 30:778–780CrossRef

Pardavi-Horvath M, Takacs L (1993) Magnetic properties of copper-magnetite nanocomposites prepared by ball milling. J Appl Phys 73:6958–6960CrossRef

Petrov YI (1982) Fizika malykh chastits (Physics of small particles). Nauka, Moscow (in Russian)

Petrov YI (1986) Klastery i malye chastitsy (Clusters and small particles). Nauka, Moscow (in Russian)

Petrov YI, Shafranovsky EA (2000) Features of ultrafine inorganic particle preparation by the gas evaporation method. BRAS Phys 64:1236–1244

Petrov YI, Shafranovsky EA (2001) Exhibition of high- and low-spin states of the high-temperature fcc phase in nanoparticles of Fe, Fe-rich and C0-rich alloys. J Nanopart Res 3:419–432CrossRef

Randrianantoandro N, Mercier AM, Hervieu M, Greneche JM (2001) Direct phase transformation from hematite to maghemite during high energy ball milling. Mater Lett 47:150–158CrossRef

Roig A, Zhang XX, Zuberek R, Tejada J, Molins E (1995) Magnetic properties of Fe/Cu multilayers. J Magn Magn Mater 140–144:559–560CrossRef

Rössler UK, Idzikowski B, Eckert D, Nenkov K, Müller K-H, Kopcewicz M, Grabias A (1999) Structural, magnetic and magnetotransport properties of melt-spun Fe₁₀Cu₉₀. IEEE Trans Magn 35:2841–2843CrossRef

Schurer PJ, Scully B, Kowalewski M, Heinrich B (2001) Mössbauer investigation of the Fe/Cu interfaces in bcc Fe/Cu/Fe(0 0 1) structures. J Magn Magn Mater 224:65–75CrossRef

Shafranovsky EA, Petrov YI (2004) Aerosol Fe nanoparticles with the passivating oxide shell. J Nanoparticle Res 6:71–90CrossRef

Shafranovsky EA, Petrov YI, Casas Ll, Molins E (2009) Structure and composition of aerosol particles obtained on evaporation of a homogeneous FeCu(50.4 at%) alloy. Doklady Phys Chem 429:246–251CrossRef

Sumiyama K, Nakamura Y, Tanaka K (1990) Mössbauer spectra and electronic structure of nonequilibrium Fe-Cu alloys produced by vapor quenching. Hyperfine Interact 53:143–158CrossRef

Tang J (1997) Magnetic properties of a few material systems made by mechanical alloying and milling. Mater Sci Forum 235–238:819–824CrossRef

Tanji Y (1971) Thermal expansion coefficient and spontaneous volume magnetostriction of Fe–Ni (fcc) alloys. J Phys Soc Jpn 31:1366–1373CrossRef

Tholence JL, Tournier R (1970) One-impurity and interaction effects on the Cu:Fe magnetization. Phys Rev Lett 25:867–871CrossRef

van Noort HM, den Broeder FJA, Draaisma HJG (1985) Mössbauer study of Cu–Fe composition-modulated thin films. J Magn Magn Mater 51:273–279CrossRef

Vandenberghe RE, Barrero CA, da Costa GM, Van San E, De Grave E (2000) Mössbauer characterization of iron oxides and (oxy)hydroxides: the present state of the art. Hyperfine Interact 126:247–259CrossRef

Vol AE (1966) Handbook of binary metallic systems; structure and properties, vol 2. Israel Program for Scientific Translations, Jerusalem (trans: Vol AE (1962) Stroenie i svoistva dvoinykh metallicheskikh system, vol 2. Fizmatgiz, Moscow, 982 p)

Weiss RJ (1963) The origin of the “Invar” effect. Proc Phys Soc 82:281–288CrossRef

Williams JM, Blythe HJ, Fedosyuk VM (1995) An investigation of electrodeposited granular CuFe alloyed films. J Magn Magn Mater 155:355–357CrossRef

Window B (1970) Hyperfine fields at ⁵⁷Fe in copper iron alloys. J Phys C 3:S323–S329CrossRef

Xiao G, Wang JQ, Xiong P (1993) Giant magnetoresistance and anomalous Hall effect in Co–Ag and Fe–Cu, Ag, Au, Pt granular alloys. IEEE Trans Magn 29:2694–2699CrossRef

Yang Y, Zhu Y, Li Q, Ma X, Dong Y, Wamg G, Wei S (2001) Mechanical alloying, fine structure and thermal decomposition of nanocrystalline fcc-Fe₆₀Cu₄₀. Physica B 293:249–259CrossRef

Yavary AR (1993) Yavari replies. Phys Rev Lett 70:3522CrossRef

Yavary AR, Desré PJ, Benameur T (1992) Mechanically driven alloying of immiscible elements. Phys Rev Lett 68:2235–2238CrossRef

Yousif A, Bouziane K, Elzain ME, Ren X, Berry FJ, Widatallah HM, Al Rawas A, Gismelseed A, Al-Omari IA (2004) Magnetic properties of nanocrystalline Fe_xCu_1−x alloys prepared by ball milling. Hyperfine Interact 156–157:213–221CrossRef

Title: Structural and Mössbauer studies of aerosol FeCu nanoparticles in a wide composition range
Authors: E. A. Shafranovsky
Yu. I. Petrov
Ll. Casas
E. Molins
Publication date: 01-10-2011
Publisher: Springer Netherlands
Published in: Journal of Nanoparticle Research / Issue 10/2011
Print ISSN: 1388-0764
Electronic ISSN: 1572-896X
DOI: https://doi.org/10.1007/s11051-011-0470-4

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