Temperature dependences of surface magnetoelastic constants of ultrathin Fe/GaAs (001) films

Temperature dependences of surface magnetoelastic constants of ultrathin Fe/GaAs (001) films

The magnetoelastic constants of epitaxial iron films prepared by dc magnetron sputtering on single crystal GaAs (001) substrate in argon atmosphere and covered with a protective Si layer have been investigated in the temperature range 10–300 K by means of the strain modulated ferromagnetic resonan...

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Дата:2012
Автори: Żuberek, R., Nesteruk, K., Fronc, K., Piechota, S., Szymczak, H.
Формат: Стаття
Мова:English
Опубліковано: Фізико-технічний інститут низьких температур ім. Б.І. Вєркіна НАН України 2012
Назва видання:Физика низких температур
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К 80-летию Виктора Валентиновича Еременко
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Цитувати:Temperature dependences of surface magnetoelastic constants of ultrathin Fe/GaAs (001) films / R. Żuberek, K. Nesteruk, K. Fronc, S. Piechota, H. Szymczak // Физика низких температур. — 2012. — Т. 38, № 9. — С. 1058-1061. — Бібліогр.: 20 назв. — англ.

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spelling nasplib_isofts_kiev_ua-123456789-1176142025-02-23T19:26:19Z Temperature dependences of surface magnetoelastic constants of ultrathin Fe/GaAs (001) films Żuberek, R. Nesteruk, K. Fronc, K. Piechota, S. Szymczak, H. К 80-летию Виктора Валентиновича Еременко The magnetoelastic constants of epitaxial iron films prepared by dc magnetron sputtering on single crystal GaAs (001) substrate in argon atmosphere and covered with a protective Si layer have been investigated in the temperature range 10–300 K by means of the strain modulated ferromagnetic resonance. It has been shown that the magnetoelastic constants strongly depend on the thickness of the film. The surface components of the magnetoelastic constants have been determined and analyzed within the Néel and dipolar models. The proposed analysis of experimental data gives chance for deeper insight into mechanisms responsible for magnetostriction of iron thin films. The work was supported in part by Polish MNiSW 2048/B/H03/2008/34 grant. The substrates of GaAs supplied by Institute of Electronic Materials Technology are kindly acknowledged. 2012 Article Temperature dependences of surface magnetoelastic constants of ultrathin Fe/GaAs (001) films / R. Żuberek, K. Nesteruk, K. Fronc, S. Piechota, H. Szymczak // Физика низких температур. — 2012. — Т. 38, № 9. — С. 1058-1061. — Бібліогр.: 20 назв. — англ. 0132-6414 PACS: 75.70.Cn, 75.80.+q, 75.70.Ak https://nasplib.isofts.kiev.ua/handle/123456789/117614 en Физика низких температур application/pdf Фізико-технічний інститут низьких температур ім. Б.І. Вєркіна НАН України
institution Digital Library of Periodicals of National Academy of Sciences of Ukraine
collection DSpace DC
language English
topic К 80-летию Виктора Валентиновича Еременко
К 80-летию Виктора Валентиновича Еременко
spellingShingle К 80-летию Виктора Валентиновича Еременко
К 80-летию Виктора Валентиновича Еременко
Żuberek, R.
Nesteruk, K.
Fronc, K.
Piechota, S.
Szymczak, H.
Temperature dependences of surface magnetoelastic constants of ultrathin Fe/GaAs (001) films
Физика низких температур
description The magnetoelastic constants of epitaxial iron films prepared by dc magnetron sputtering on single crystal GaAs (001) substrate in argon atmosphere and covered with a protective Si layer have been investigated in the temperature range 10–300 K by means of the strain modulated ferromagnetic resonance. It has been shown that the magnetoelastic constants strongly depend on the thickness of the film. The surface components of the magnetoelastic constants have been determined and analyzed within the Néel and dipolar models. The proposed analysis of experimental data gives chance for deeper insight into mechanisms responsible for magnetostriction of iron thin films.
format Article
author Żuberek, R.
Nesteruk, K.
Fronc, K.
Piechota, S.
Szymczak, H.
author_facet Żuberek, R.
Nesteruk, K.
Fronc, K.
Piechota, S.
Szymczak, H.
author_sort Żuberek, R.
title Temperature dependences of surface magnetoelastic constants of ultrathin Fe/GaAs (001) films
title_short Temperature dependences of surface magnetoelastic constants of ultrathin Fe/GaAs (001) films
title_full Temperature dependences of surface magnetoelastic constants of ultrathin Fe/GaAs (001) films
title_fullStr Temperature dependences of surface magnetoelastic constants of ultrathin Fe/GaAs (001) films
title_full_unstemmed Temperature dependences of surface magnetoelastic constants of ultrathin Fe/GaAs (001) films
title_sort temperature dependences of surface magnetoelastic constants of ultrathin fe/gaas (001) films
publisher Фізико-технічний інститут низьких температур ім. Б.І. Вєркіна НАН України
publishDate 2012
topic_facet К 80-летию Виктора Валентиновича Еременко
url https://nasplib.isofts.kiev.ua/handle/123456789/117614
citation_txt Temperature dependences of surface magnetoelastic constants of ultrathin Fe/GaAs (001) films / R. Żuberek, K. Nesteruk, K. Fronc, S. Piechota, H. Szymczak // Физика низких температур. — 2012. — Т. 38, № 9. — С. 1058-1061. — Бібліогр.: 20 назв. — англ.
series Физика низких температур
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AT piechotas temperaturedependencesofsurfacemagnetoelasticconstantsofultrathinfegaas001films
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fulltext © R. Żuberek, K. Nesteruk, K. Fronc, S. Piechota, and H. Szymczak, 2012 Low Temperature Physics/Fizika Nizkikh Temperatur, 2012, v. 38, No. 9, pp. 1058–1061 Temperature dependences of surface magnetoelastic constants of ultrathin Fe/GaAs (001) films R. Żuberek, K. Nesteruk, K. Fronc, S. Piechota, and H. Szymczak Institute of Physics, Polish Academy of Sciences, 32/46 Al. Lotników, 02-668 Warsaw, Poland E-mail: szymh@ifpan.edu.pl Received April 10, 2012 The magnetoelastic constants of epitaxial iron films prepared by dc magnetron sputtering on single crystal GaAs (001) substrate in argon atmosphere and covered with a protective Si layer have been investigated in the temperature range 10–300 K by means of the strain modulated ferromagnetic resonance. It has been shown that the magnetoelastic constants strongly depend on the thickness of the film. The surface components of the magnetoelastic constants have been determined and analyzed within the Néel and dipolar models. The proposed analysis of experimental data gives chance for deeper insight into mechanisms responsible for magnetostriction of iron thin films. PACS: 75.70.Cn Magnetic properties of interfaces (multilayers, superlattices, heterostructures); 75.80.+q Magnetomechanical effects, magnetostriction; 75.70.Ak Magnetic properties of monolayers and thin films. Keywords: magnetoelastic constants, ferromagnetic resonance, iron films. 1. Introduction The films of iron deposited on GaAs have been of strong interest for their possible applications in magneto- electronic devices. It was shown that Fe films with thick- ness of 5 monolayers or more epitaxially grown at room temperature (RT) on GaAs (001) surfaces, are ferromag- netically ordered at room temperature with nearly bulk magnetic moment per atom [1]. It is generally accepted that magnetic anisotropy essentially control the hysteretic behavior of ferromagnets and consequently determine most of the parameters (e.g., coercivity, permeability, energy of magnetic domain walls) important for practical applica- tions. Therefore, the understanding of magnetic aniso- tropies in Fe/GaAs films is of crucial importance for the development of various spintronic devices. In this particu- lar case the magnetic anisotropy of the thin films is deter- mined to a large degree by surface or interface effects. The interfacial anisotropy does exist not only in the out-of- plane direction, but can also arise within the plane of the film. In thin single crystal Fe films on GaAs (001) sub- strate an uniaxial anisotropy is observed with easy axis in the [110] direction [2] below a critical film thickness. The uniaxial magnetic anisotropy has already been observed in thicker Fe films on GaAs (001) [3,4]. There have been speculations on the origin of this anisotropy. It was sug- gested that this anisotropy is related to the presence of a Fe3Ga2–xAsx at the interface [4]. More results, however, support the explanation of the uniaxial term by the intrinsic anisotropy of the dangling bonds at the GaAs (001) surface [2,3,5,6]. The thickness and stress dependence of magnetoelastic constants of iron films have also been reported by several authors (see, e.g., [5,7]). In the present paper we continue our studies of the magnetoelastic constants of the iron films with different thickness but with similar stresses at the surface/interface [6,8]. To explore this problem further the epitaxial iron films prepared by dc magnetron sputter- ing on single crystal GaAs (001) substrate in argon atmos- phere and covered with a protective Si layer have been investigated from 10 to 300 K by means of the strain mod- ulated ferromagnetic resonance (SMFMR). 2. Experimental The Fe films in form of a wedge and the thickness range from 3 to 6 nm, were grown by dc magnetron sput- tering on GaAs (001) single crystal substrate at room temperature. Ar were used as a sputter gas at pressures of 3·10–1 Pa. Prior to the thin film deposition, polished semiinsulating GaAs (001) substrates were cleaned in tri- chloroethylene, methanol and rinsed in deionized water. Then the substrates were dipped into a solution of 6H2SO4:1H2O2:1H2O (by volume) for 15 min and rinsed Temperature dependences of surface magnetoelastic constants of ultrathin Fe/GaAs (001) films Low Temperature Physics/Fizika Nizkikh Temperatur, 2012, v. 38, No. 9 1059 in deionized water. Next the GaAs substrates were dipped into solution of 10H2O:1HCl without subsequent rinsing with ultrapure water. After etching procedure the substrate was immediately mounted to the substrate holder and load- ed into loadlock chamber of sputtering system. The time needed to transfer the substrate from HCl solution into UHV environment with pressure 10–6 Pa not exceeded 20 min. In order to prevent oxidation of magnetic layer, the iron films were covered with a protective Si layer of 7.5 nm thick. 3. Ferromagnetic resonance conditions SMFMR experiments were performed using a standard X-band spectrometer operating at 9.2 GHz with 100 kHz field modulation and 130 kHz strain modulation. The dc magnetic field was applied in the plane of the film along the [100] and [110] directions. The SMFMR spectra were analyzed using a coordinate system in which the magneti- zation of the film M and the external magnetic field H make angles θ and θH with respect to the film normal and angles φ and φH with respect to the [100] axis of the film. In our experiment θH = π/2. In order to calculate the resonance frequency we have used the approach developed by Suhl [9]. Considering the uniaxial and cubic anisotropy energies the free energy den- sity of the system is 2 2 effsin cos ( ) 2 cosHF MH Mθ φ π θφ= − − + + 4 2 2 2 21 (sin sin 2 sin 2 ) sin cos ( 45 ) . 4 u K Kθ φ θ θ φ+ + − − ° (1) It is useful to define the anisotropy fields 12 / , 2 /k s u u sH K M H K M= = . (2) The terms containing Ku represents in plane uniaxial ani- sotropy energy, K1 is cubic anisotropy constant. The effec- tive magnetization term consists of saturation magnetiza- tion and out of plane anisotropy field: eff4 4 2 /s sM M K Mπ π ⊥= + . (3) The equilibrium conditions for the magnetization and the resonance condition for the FMR can be found using the following equations [9]: 22 2 2 2 2 2 22 1 0, , sins F F F F F M ω θ φ γ θ φθ θ φ ⎡ ⎤⎛ ⎞⎛ ⎞∂ ∂ ∂ ∂ ∂⎢ ⎥= = = −⎜ ⎟ ⎜ ⎟∂ ∂ ⎝ ⎠ ∂ ∂⎢ ⎥∂ ⎝ ⎠∂⎣ ⎦ (4) where ω is the circular frequency, γ is the giromagnetic ratio. For the strain modulated FMR (SMFMR) the magnetoelastic energy [10] should be added to the free energy of the system: eff ijkl ijklmni j kl i k kl mn i j klME ijklF BB Dα α ε α α ε ε α α ε= + = , (5) where the first term is linear and second nonlinear func- tions of the strain. For cubic crystal the linear part of the magnetoelastic energy can be written as 2 2 2 1 1 11 2 22 3 33 2 1 2 12 2 3 23 1 3 13 ( ) 2 ( ) , ME bF b α ε α ε α ε α α ε α α ε α α ε = + + + + + + (6) 1111 11221 2 1313, 2 , Bb bB B= − = (7) where b1 and b2 are the magnetoelastic constants, the εij and αi are the components of strain tensor and the direction cosines of M with respect to the cubic axes, respectively. For thin films, in which the thickness (t) of the film is smaller than the exchange length, the effective anisotropy and magnetoelastic constants can be written as ([11] and reference therein) eff ( ) ( ) ( ) 2v s n n nK K K t = + , (8) where 1 2 ( ) ( ) ( )2 s s s n n nK K K= + (9) and eff ( ) ( ) ( ) 2v s n n nb b b t = + , (10) n = u for uniaxial and 1 for in-plane cubic anisotropy and n = 1 or 2 for magnetoelastic constants. In (9) the contribu- tions from both interfaces are considered. 4. Experimental results The SMFMR measurements with dc magnetic field pa- rallel to [110] direction allow determination of the effec- tive magnetoelastic constant eff 2b . As examples the FMR derivative spectra for the film with 4 nm thickness for magnetic and strain modulation measured at 10 K and RT are shown in Fig. 1. The temperature dependence of eff 2b Fig. 1. The typical FMR spectra for field directed along [110] axis for magnetic and strain modulation measured at 10 K and RT for the Fe film with the thickness of 4 nm. Strain Magnetic B, mT FM R sp ec tra , a rb . u ni ts 600 400 200 0 –200 –400 –600 –800 50 60 70 80 90 100 R. Żuberek, K. Nesteruk, K. Fronc, S. Piechota, and H. Szymczak 1060 Low Temperature Physics/Fizika Nizkikh Temperatur, 2012, v. 38, No. 9 for the films with different thicknesses are shown in Fig. 2. The fitted values of the volume and surface (interface be- tween GaAs and Fe from one side and Fe/Si from the se- cond one) magnetoelastic constants for several tempera- tures are shown in Figs. 3 and 4. The values of the magnetoelastic constant b2 of bulk bcc Fe [12,13] are also displayed. The surface magnetoelastic constants seem to have origin similar to that established for the surface ani- sotropy. 5. Comparison with the Néel and dipolar models Usually, in order to compare the surface in-plane cubic and uniaxial anisotropy constants with the Néel [14,15] or dipolar [16,17] models the effective anisotropy constant is written in another way [18]. Assuming that the thickness of one monolayer is equal d then the thickness of the film will be equal t = Nd where N is the number of atomic layers in the film. In ideal structure of the film there are two surface layers of thickness d and N – 2 volume layers. Then effec- tive anisotropy constant can be written as eff ( ) ( ) ( )( 2) 2v ss n n nK Nd K N d K= − + , (11) where 1 2 ( ) ( ) ( )2 ss ss ss n n nK K K= + , (12) and ( ) ss nK d is the proper surface anisotropy constant calcu- lated, e.g., in the Néel or dipolar model. The following dependence between ( ) s nK and ( ) ss nK results from Eqs. (1) and (4): ( ) ( ) ( ) s ss v n n nK K K d= − . (13) It means that the measured surface anisotropy constant ( )( )s nK depends additionally on volume contribution ( 1 vK ). In some cases [11] the volume anisotropy constant for the uniaxial anisotropy is equal to zero and therefore both surface anisotropy constants are the same ( ( ) ( ) s ss u uK K= ). The in-plane surface cubic anisotropy constant obtained from linear dependence of the effective anisotropy constant on inverse film thickness is less than calculated one by 1 vdK . For the films with the same surface anisotropy con- stant but different volume anisotropy constant the linear dependence surface anisotropy constant ( 1 sK ) on the vol- ume anisotropy constant ( 1 vK ) is observed (see for in- stance Fig. 4 in paper [11]). Usually magnetic anisotropy and magnetostriction have the same origin. Therefore, in the case of magnetoelastic constant the same problem appears as in magnetic anisot- ropy constant and, consequently, the same formula for simulating surface magnetoelastic constant ( 2 sb ) and prop- er surface magnetoelastic constant ( 2 ssb ) should be used 2 2 2 s ss vb b b d= − . (14) According to literature (e.g., [19]) the dependence of the magnetoelastic constants on the thickness of magnetic layer arises as an intrinsic or an extrinsic effect. The intrin- Fig. 2. The temperature dependence of eff 2b for films with differ- ent thicknesses. b 2 , 1 0 J/ m 6 2 t = 3.6 nm t = 4.4 nm t = 5.8 nm t = 4.0 nm T, K Fig. 4. The fitted values of the volume magnetoelastic constants for several temperatures. The values of magnetoelastic constant b2 of bulk bcc Fe are also displayed. Films Bulk 7 6 5 4 3 b 2V , 10 J/ m 6 2 Fig. 3. The fitted values of the surface (interface between GaAs and Fe from one side and Fe/Si from the second one) magneto- elastic constant b2 for several temperatures. T, K –1.6 –1.8 –2.0 –2.2 –2.4 –2.6 –2.80 50 100 150 200 250 300 2 , 10 J/ m b 2s –4 2 Temperature dependences of surface magnetoelastic constants of ultrathin Fe/GaAs (001) films Low Temperature Physics/Fizika Nizkikh Temperatur, 2012, v. 38, No. 9 1061 sic effect is related to the broken symmetry of atoms at the interface (see, e.g., the well-known Néel model [14,15]). According to the Néel model the surface magnetoelastic tensor, ss ijklB , for the bcc structure and for (001) surface has cubic symmetry and magnetoelastic constant ( 2 ssb ) is equal to [15] 2 1313 42 ( ), 9 ss ss sb B n p mr= = + (15) where ns is the density of surface atoms and p for the bcc iron is equal to – 1.5326·10–23 J, mr = 12.0·10–23 J. Then 3 2 3 2· ·2 20.57 10 J/m , and 0.5 10 J/mss sb b− −= = − (16) which is about several times smaller than values obtained in experiment. The extrinsic effects arise mainly due to the misfit dis- locations, interdiffusion and even due to the surface rough- ness. The relatively large scatter of the experimental data seen in Figs. 3, 4 suggests that interface Fe–GaAs is not flat but rather rough. The roughness was shown to give considerable contribution to the surface anisotropy and magnetostriction [20]. The roughness depends on various factors which are difficult to remove. 5. Conclusion We have grown epitaxial iron films on single crystalline GaAs (001) substrates with Ar as a sputtering gas. The films were covered with Si overlayers. The magneto- striction constants have been measured by SMFMR meth- od. The small FMR linewidth of the measured films indi- cates a high crystalline quality of the Fe layers. It has been found that magnetostriction constants are composed of surface and bulk contributions dependend on temperature. The bulk magnetoelastic constants were equal to the values found for bulk Fe. The surface anisotropy and surface magnetostriction are related first of all to the effects of broken symmetry of atoms at the interfaces. This observa- tion seems to be related to tetragonal strain due to lattice mismatch. Acknowledgments The work was supported in part by Polish MNiSW 2048/B/H03/2008/34 grant. The substrates of GaAs sup- plied by Institute of Electronic Materials Technology are kindly acknowledged. 1. M. Zolfl, M. Brockmann, M. Kohler, S. Kreuzer, T. Schweinbock, S. Miethaner, F. Bensch, and G. Bayreuther, J. Magn. Magn. Mater. 175, 16 (1997). 2. M. Brockmann, M. Zolfl, S. Miethaner, and G. Bayreuther, J. Magn. Magn. Mater. 198–199, 384 (1999). 3. J.J. Krebs, B.T. Jonker, and G.A. Prinz, J. Appl. Phys. 61, 2596 (1987). 4. A. Filipe, A. Schuhl, and P. Galtier, Appl. 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