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Ferromagnetic resonance study of polycrystalline Fe_1-xV_x alloy thin films
J-M. L. Beaujour¹, J. Z. Sun², A. D. Kent^1
1 Department of Physics, New York University, New York, USA,
²IBM T. J. Watson Research Center - Yorktown Heights, NY 10598, USA.
Accepted for publication in J. Appl. Phys. (2008)

• Abstract: Ferromagnetic resonance has been used to study the magnetic properties and magnetization dynamics of polycrystalline Fe_1-xV_x alloy films with 0≤ x <0.7. Films were produced by co-sputtering from separate Fe and V targets, leading to a composition gradient across a Si substrate. FMR studies were conducted at room temperature with a broadband coplanar waveguide at frequencies up to 50 GHz using the flip-chip method. The effective demagnetization field 4pM_eff and the Gilbert damping parameter G have been determined as a function of V concentration. The results are compared to those of epitaxial FeV films.

Ferromagnetic resonance study of sputtered Co|Ni multilayers
J-M. L. Beaujour¹, W. C. Chen¹, K. Krycka², C-C. Kao², J. Z. Sun³, A. D. Kent^1
1 Department of Physics, New York University, New York, USA,
² Brookhaven National Laboratory, Upton, New York 11973, USA
³IBM T. J. Watson Research Center - Yorktown Heights, NY 10598, USA.
Accepted for publication in Eur. Phys. J. B 2007

• Abstract: We report on room temperature ferromagnetic resonance (FMR) studies of [t Co|2t Ni]´N sputtered films, where 0.1 £ t £ 0.6 nm. Two series of films were investigated: films with same number of Co|Ni bilayer repeats (N=12), and samples in which the overall magnetic layer thickness is kept constant at 3.6 nm (N=1.2/t). The FMR measurements were conducted with a high frequency broadband coplanar waveguide up to 50 GHz using a flip-chip method. The resonance field and the half power linewidth were measured as a function of frequency for the field in-plane and field normal to the plane, and as a function of angle to the plane for several frequencies. For both sets of films, we find evidence for the presence of first and second order anisotropy constants, K₁ and K₂. The anisotropy constants are strongly dependent on the thickness t, and to a lesser extent on the total thickness of the magnetic multilayer. The Landé g-factor increases with decreasing t and is practically independent of the multilayer thickness. The magnetic damping parameter a, estimated from the linear dependence of the linewidth DH on frequency, in the field in-plane geometry, increases with decreasing t. This behaviour is attributed to an enhancement of spin-orbit interactions with t decreasing and to the interfacial non-local Gilbert damping effect.

Magnetization damping in polycrystalline Co ultra-thin films: Evidence for non-local effects
J-M. L. Beaujour¹, J. H. Lee¹, K. Krycka², C-C. Kao², A. D. Kent^1
1 Department of Physics, New York University, New York, USA,
² Brookhaven National Laboratory, Upton, New York 11973, USA
Phys. Rev. B 74, 214405  (2006).

• Abstract: The magnetic properties and magnetization dynamics of polycrystalline ultra-thin Co layers were investigated using a broadband ferromagnetic resonance (FMR) technique at room temperature. A variable thickness (1 £ t £ 10 nm) Co layer is sandwiched between 10 nm thick Cu layers (10 nm Cu|Co|10 nm Cu), while materials in contact with the Cu outer interfaces are varied to determine their influence on the magnetization damping. The resonance field and the linewidth were studied for in-plane magnetic fields in field swept experiments at a fixed frequency, from 4 to 25 GHz. The Co layers have a lower magnetization density than the bulk, and an interface contribution to the magnetic anisotropy normal to the film plane. The Gilbert damping, as determined from the frequency dependence of the linewidth, increases with decreasing Co layer thickness for films with outer Pt layers. This enhancement is not observed in structures without Pt layers. The result can be understood in terms of a non-local contribution to the damping due to spin pumping from Co through the Cu layer and spin relaxation in Pt layers. Pt layers just 1.5 nm thick are found to be suffcient to enhance the damping and thus act as efficient "spin-sinks." In structures with Pt outer layers, this non-local contribution to the damping becomes predominant when the Co layer is thinner than 4 nm.

cond-mat/0602243

Ferromagnetic resonance study of polycrystalline Cobalt ultrathin films
J-M. L. Beaujour¹, W. Chen¹, A. D. Kent¹, J. Z. Sun^2
1 Department of Physics, New York University, New York, USA,
² IBM T. J. Watson Research Center, Yorktown Heights, NY 10598, USA
J. Appl. Phys. 99, 08N503 (2006)

• Abstract:  We present room temperature ferromagnetic resonance (FMR) studies of polycrystalline ||Pt/10 nm Cu/t Co/10 nm Cu/Pt|| films as a function of Co layer thickness (1 £ t £ 10 nm) grown by evaporation and magnetron sputtering. FMR was studied with a high frequency broadband coplanar waveguide (up to 25 GHz) using a flip-chip method. The resonance field and the linewidth were measured as a function of the ferromagnetic layer thickness. The evaporated films exhibit a lower magnetization density (M_s = 1131 emu/cm³) compared to the sputtered films (M_s= 1333 emu/cm³), with practically equal perpendicular surface anisotropy (K_s ~ -0.5 erg/cm²). For both series of films, a strong increase of the linewidth was observed for Co layer thickness below 3 nm. For films with a ferromagnetic layer thinner than 4 nm, the damping of the sputtered films is larger than that of the evaporated films. The thickness dependence of the linewidth can be understood in term of the spin pumping effect, from which the interface spin mixing conductance (g^?? S^-1) is deduced.

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Giant magneto- and anisotropic resistance in an epitaxial (110) DyFe₂/YFe₂ multilayer film
Beaujour JML, Bowden GJ, Zhukov AA, O'Neill JD, Rainford BD, de Groot PAJ, Ward RCC, Wells MR, Jansen AGM
J. Magn. Magn. Mater. 272-76: 1943-1944 Part 2 Sp. Iss. SI May 2004

• Abstract:Anisotropic and giant magneto-resistance (AMR and GMR) measurements for a molecular beam epitaxy grown (110) multilayer film [50 DyFe₂/50 YFe₂] x 40 at 100 K are reported. The film possesses a bending field B_B similar to 5 T and an irreversible switching field B_IS similar to 5 T. These features allow the study of both AMR, and GMR caused by the creation not only of longitudinal but also transverse magnetic exchange springs, in the magnetically soft YFe₂ layers. Finally, rotation experiments in applied fields show that like DyFe₂ films, there is a metastable state aligned along a [110] axis at 100 K.
  

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Neutron reflectometry studies of exchange springs in DyFe₂/YFe₂ superlattices
O'Neill JD, Langridge S, Dalgliesh RM, Zhukov AA, Beaujour JML, Bowden GJ, de Groot PAJ, Rainford BD, Ward RCC, Wells MR
J. Magn. Magn. Mater. 272-76: 1258-1259 Part 2 Sp. Iss. SI May 2004

• Abstract:Spin-polarised neutron reflectometry has been used to investigate a magnetic exchange spring, formed in a (75 DyFe₂/150 YFe₂) x 18 multilayer thin film. The existence of an exchange spring is found to enhance the level of neutron spin flipping during reflection, a strong indicator of the formation of transverse magnetic moments within the YFe₂ layers.
  

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Anisotropic magnetoresistance in epitaxial (110) DyFe₂ film: a meta-stable magnetic state at 100 K
J-M. Beaujour, G. J. Bowden, A. A. Zhukov, B. Rainford, P. de Groot, R. Ward, M. Wells
J. Magn. Magn. Mater. 257 (2-3): 270-273 (2003)

• Abstract: The direction of easy magnetisation in molecular beam epitaxy grown (110) films of DyFe₂ is known to change from [0 0 1] at low temperatures to close to [3 5 1] at room temperature. In this paper we present compelling anisotropic magneto-resistance measurements for the presence of a meta-stable magnetic state aligned along the [I 10] axis at 100K.

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Room temperature coercivities of Tb_1-xDy_xFe₂ (110) molecular beam epitaxy grown films
J-M. Beaujour, G. J. Bowden, A. A. Zhukov, B. Rainford, P. de Groot, R. Ward, M. Wells
J. Appl. Phys. (10): 8639-8640 (2003)

• Abstract: It has been known for many years that the rare-earth intermetallic compound terfenol (Tb_0.3Dy_0.7)Fe₂ is characterized by "giant magnetostriction," which has found practical applications. In this article we report the magnetic properties of a series of molecular beam epitaxially (MBE) grown (110) Tb_1-xDy_xFe₂ alloy films, on sapphire substrates. All the measurements were performed at room temperature with the field applied along an in-plane [-110] axis. However, unlike bulk Tb_1-xDy_xFe₂, it is shown that the coercivity does not fall to zero at the magic ratio of x similar to 0.7. Instead, the coercivities fall almost on a straight line, with the maximum coercivity for pure TbFe₂ (0.64 T) and the smallest for DyFe₂ (0.22 T). The difference between the bulk and MBE films is attributed to the presence of a magnetoelastic strain term, induced during crystal growth by the sapphire substrate. In practice, the measured coercivities can be described, approximately, with a modified Stoner-Wohlfarth model.

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Vector Magnetometer studies of the easy magnetization direction in epitaxially grown DyFe₂ film
A. A. Zhukov, G. J. Bowden, J-M. Beaujour, B. Rainford, P. de Groot, R. Ward, M. Wells
J. Magn. Magn. Mater. 270: 312-320 (2004)

• Abstract: A vector vibrating sample magnetometer has been used to determine the direction of easy magnetisation in a thin film of DyFe₂. The 4000 Angstrom thick film, with a [110] growth direction, was prepared using molecular beam epitaxy. The results show that the direction of easy magnetisation is temperature dependent. At 4 K this direction corresponds to the [0 0 1] type axes. But at 290 K, the easy axis is close to a [-110] direction, but pointing out of the plane of the film at angle of similar to (14 +/- 3)degrees. On the basis of the vector magnetometer results at 290 K we find two easy magnetisation axes close to [-350] or [-530] (and opposite directions). Finally, it is shown that DyFe₂ films are unique in that the remanent magnetisation can be manipulated to point either in or out of the plane of the film.

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Modeling the magnetic exchnage properties of DyFe2 - YFe2 superlattices
G. J. Bowden, J-M. Beaujour, A. Zhukov, P. de Groot, B. Rainford, R. Ward, M. Wells
J. Appl. Phys. 93 (10): 6480 (2003)

• Abstract: The Stoner-Wohlfarth model has proved reasonably successful in describing the coercivities of antiferromagnetically coupled DyFe₂/YFe₂ hard/soft superlattices in the absence of magnetic exchange springs. In particular, the coercivity rises sharply as the net magnetic moment of the superlattice approaches zero. However the situation becomes more complicated as the thickness of the YFe₂ layers is increased. Two distinct "instability fields" can be identified: the bending field B_B, signifying the onset of a magnetic exchange spring, and the irreversible switching field B-IS associated with magnetic reversal. We have developed a computational model to address this problem. In particular, it is shown that the two instability fields in question are characterized by vanishing eigenvalues in the matrix formed by the double energy derivatives partial d²E/dq_idq_j , where E is the total energy and q_i the angle of each individual monolayer. It is shown that the model provides a very good description of the M-B-app loops of DyFe₂/YFe₂ multilayer films. In particular, the coercivity of a nearly magnetically compensated multilayer (75 Angstrom DyFe₂/150 Angstrom YFe₂) is much reduced below the prediction of the Stoner-Wolhfarth model, in accord with experiment.

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Some universal results for magnetic exchange springs magnets
G. J. Bowden, G. Daniell, S. Gordeev, J-M. Beaujour, P. de Groot, B. Rainford, R. Ward, M. Wells
J. Magn. Magn. Mater. 240 (1-3):556-558 (2002)

• Abstract: We present some universal results for exchange springs in multilayer systems with alternating hard and soft layers. In particular, the reduced magnetisation <cos q>, for both symmetric exchange springs (0-->f-->0) and 180degrees exchange springs (0-->p), is given in terms of elliptic functions. The result for the symmetric exchange spring is found to be in good accord with experimental results on MBE grown DyFe₂/YFe₂ multilayers.

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Effect of exchange springs on the coercivity of DyFe₂ - YFe₂ superlattices
J-M. Beaujour, G. J. Bowden, S. Gordeev, P. de Groot, B. Rainford, R. Ward, M. Wells
J. Magn. Magn. Mater. 226-230:1714-6 (2001)

• Abstract: The coercivity of MBE-grown Laves-phase DyFe₂-YFe₂ thin-layered ( less than or equal to 50 Angstrom) superlattice samples, with a (110) growth direction, can be varied by adjusting the relative thickness of the YFe₂ and DyFe₂ layers. However, for sufficiently thick layers, the coercivity is found to be dependent on the thickness of the YFe₂, layers, even when the ratio of DyFe₂/YFe₂, is fixed. This feature is illustrated using the superlattice films [wDyFe₂/wYFe₂]x40, with w = 75, 100 and 150 Angstrom. The underlying reason for the decrease in coercivity with increasing width w, is traced to the action of the magnetic exchange springs in the YFe₂ layers.

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Exchange springs in YFe2 dominated DyFe₂ - YFe₂ superlattices
J-M. Beaujour, G. Bowden, S. Gordeev, P. de Groot, B. Rainford, R. Ward, M. Wells
J. Magn. Magn. Mater. 226-230:1870-2 (2001)

• Abstract: MBE methods have been used to grow single-crystal Laves-phase DyFe₂-YFe₂ superlattice samples with a (1 1 0) growth direction. In this paper, magnetisation curves for the YFe₂ dominated multilayer samples [wDyFe₂/4wYFe₂] x N, where w = 20, 30, 40, and 50 Angstrom, and N = 40, 27, 20, and 16, respectively, are presented and discussed. It will be shown that the measured M-H loops are dominated by magnetic exchange springs, which reduce the magnetic coercivity, considerably. In particular, it is possible to engineer samples with a negative coercivity.

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Negative coercivity in epitaxially grown (110) DyFe₂ - YFe₂ superlattices
J-M Beaujour, G. J. Bowden, S. Gordeev, P. de Groot, B. Rainford, R. Ward, M. Wells
Appl. Phys. Lett. 78: 964 (2001)

• Abstract: Molecular beam epitaxial methods have been used to grow single crystal Laves phase DyFe₂/YFe₂ superlattice samples with a (110) growth direction. Detailed magnetization curves have been obtained for YFe₂ dominated multilayer samples [wDyFe₂/4wYFe(2)]x16 with w=45, 50, and 55 Angstrom. In particular, it is shown that the formation of magnetic exchange springs in the magnetically soft YFe₂ layers, can be used to engineer multilayer samples with a negative coercivity. Further, by using asymmetric field cycling procedures, we have investigated the irreversible parts of the M-B loop, associated with the switching of the DyFe₂ multilayers.

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Giant magneto-resistance by exchange springs in DyFe₂ - YFe₂ superlattices
S. Gordeev, J-M. Beaujour, G. J. Bowden, P. de Groot, B. Rainford, R. Ward, M. Wells
Phys. Rev. Lett. 87: 186808 (2001)

• Abstract: Magnetization and magnetoresistance measurements are reported for antiferromagnetically coupled DyFe₂/YFe₂ multilayers in fields up to 23 T It is demonstrated that the formation of short exchange springs (similar to 20 Angstrom) in the magnetically soft YFe₂ layers results in a giant magnetoresistance as high as 32% in the spring region. It is shown that both the magnitude of the effect and its dependence on magnetic field are in good agreement with the theory of Levy and Zhang for domain wall induced giant magnetoresistance.

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Spin configurations and negative coercivity in epitaxially grown DyFe₂ - YFe₂ superlattices
S. Gordeev, J-M. Beaujour, G. J. Bowden, P. de Groot, B. Rainford, R. Ward, M. Wells
J. Appl. Phys. 89: 6828 (2001)

• Abstract: Molecular beam epitaxial methods have been used to grow single crystal Laves phase DyFe₂/YFe₂ superlattice samples with a (110) growth direction. In particular, the magnetic properties of the YFe₂ dominated multilayer samples [wDyFe₂/4wYFe₂] x N with w = 20, 30, 40, 45, 50, and 55 Angstrom are presented and discussed. In principle, the multilayer films should possess similar magnetic properties because they are all nominally Dy_0.2Y_0.8Fe₂. However, it is shown that their magnetic properties depend strongly on the thickness of the DyFe₂ layers w. Those films with w greater than or equal to 45 Angstrom possess negative coercivities, while those with w less than or equal to 40 Angstrom are positive. It is argued that this behavior can be understood in terms of a strong increase of the intrinsic coercivity of the DyFe₂/YFe₂ superlattice, taken as a whole, as w is reduced. For w less than or equal to 40 Angstrom almost none of the DyFe₂ moments can be flipped over in the available field range (12 T).

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Discrete exchange-springs in magnetic multilayer samples
G. J. Bowden, J-M. Beaujour, S. Gordeev, P. de Groot, B. Rainford, R. Ward, M. Wells
J. Phys. Cond. Matt. 12: 9335-9346 (2000)

• Abstract: The properties of soft magnetic exchange-springs in both bilayer and multilayer samples are investigated, with particular emphasis on the discrete nature of the spring. it is shown that, in a mean-field model, a very simple relationship exists between the bending field B_B, the exchange field B_EX and the number of monolayers N in the soft magnetic layer. For bilayers B_B/B_EX = (p /2N)², whereas for multilayers B_B/B_EX = (p /N)² . In addition, it is shown that Jacobi elliptic functions, originally used by Goto at al for continuous bilayer springs, provide a surprisingly robust description of discrete bilayer and symmetric multilayer exchange-springs. Finally, the problem of soft exchange-spring penetration into neighboring hard magnetic layers is discussed. Calculations show that this is an important effect, which leads to a reduction in the bending field Bs.

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Exchange springs in antiferromagnetically coupled DyFe₂ - YFe₂ superlattices
M. Sawicki, G. J. Bowden, P. de Groot, B. Rainford, J-M. Beaujour, R. Ward, M. Wells
Phys. Rev. B 62: 5817-20 (2000)

• Abstract: Molecular beam epitaxy methods have been used to grow single-crystal Laves phase DyFe₂-YFe₂, superlattice samples with a (110) growth direction. In this paper, magnetization curves for the multilayer samples [wDyFe₂ / wYFe₂] x 40, with w = 50, 75, 100, 150, and 300 Angstrom, are presented and discussed. Below T_C, the magnetic moments of the DyFe₂ layers are coupled antiferromagnetically to those of the YFe₂ layers. However, in applied fields, it is possible to generate magnetic exchange springs in the YFe₂ layers, with well-defined bending (onset) fields B_B. In particular, it is demonstrated, both experimentally and theoretically, that the bending field B_B is closely proportional to 1/w², where w is the thickness of the magnetically soft YFe₂ layer.

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Engineering coercivity in epitaxially grown (110) films of DyFe₂ - YFe₂ superlattices
M. Sawicki, G. J. Bowden, P. de Groot, B. Rainford, J-M. Beaujour, R. Ward, M. Wells
Appl. Phys. Lett. 77: 573-5 (2000)

• Abstract: Molecular beam epitaxial methods have been used to grow single crystal Laves phase DyFe₂-YFe₂ superlattice samples with a (110) growth direction. It is shown that it is possible, in principle, to engineer a desired coercivity between the limits K_(DyFe2) less than or equal to K less than or equal to infinity. This can be achieved by adjusting the relative thickness of the individual DyFe₂ and YFe₂ layers, in multilayer films This novel feature is illustrated, using the superlattice films [x Angstrom DyFe₂ / (100-x) Angstrom YFe₂]x40, with x=80, 60, 50, and 45. It is found that the measured coercivity is in semiquantitative agreement with a simple theoretical expression, for the nucleation fields in both bilayer and multilayer compounds. However, in practice, exchange spring penetration into the DyFe₂ layers can set a limit to the maximum coercivity that can be achieved.
  

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