In a thin magnetic nanostripe, an antivortex nucleates inside a moving domain wall when driven by an in-plane magnetic field greater than the so-called Walker field. The nucleated antivortex must cross the width of the nanostripe before the domain wall can propagate again, leading to low average domain wall speeds. A large out-of-plane magnetic field, applied perpendicularly to the plane of the nanostripe, inhibits the nucleation of the antivortex leading to fast domain wall speeds for all in-plane driving fields. We present micromagnetic simulation results relating the antivortex dynamics to the strength of the out-of-plane field. An asymmetry in the motion is observed which depends on the alignment of the antivortex core magnetic moments to the direction of the out-of-plane field. The size of the core is directly related to its crossing speed, both depending on the strength of the perpendicular field and the alignment of the core moments and direction of the out-of-plane field

Breitbach, Eric C.

Kunz, Andrew

Smith, Andy J.

English

epublications@Marquette

Marquette Universitye-Publications@MarquettePhysics Faculty Research and Publications Physics, Department of1-1-2009Antivortex Dynamics in Magnetic NanostripesAndrew KunzMarquette University, andrew.kunz@marquette.eduEric C. BreitbachMarquette UniversityAndy J. SmithMarquette UniversityPublished version. Reproduced from Journal of Applied Physics, Vol. 105, No. 7 (2009), with thepermission of AIP Publishing. DOI. © 2009 American Institute of Physics. Used with permission.Antivortex dynamics in magnetic nanostripesAndrew Kunz,a Eric C. Breitbach, and Andy J. SmithPhysics Department, Marquette University, Milwaukee, Wisconsin 53233, USAPresented 11 November 2008; received 16 September 2008; accepted 6 October 2008;published online 30 January 2009In a thin magnetic nanostripe, an antivortex nucleates inside a moving domain wall when driven byan in-plane magnetic field greater than the so-called Walker field. The nucleated antivortex mustcross the width of the nanostripe before the domain wall can propagate again, leading to low averagedomain wall speeds. A large out-of-plane magnetic field, applied perpendicularly to the plane of thenanostripe, inhibits the nucleation of the antivortex leading to fast domain wall speeds for allin-plane driving fields. We present micromagnetic simulation results relating the antivortexdynamics to the strength of the out-of-plane field. An asymmetry in the motion is observed whichdepends on the alignment of the antivortex core magnetic moments to the direction of theout-of-plane field. The size of the core is directly related to its crossing speed, both depending onthe strength of the perpendicular field and the alignment of the core moments and direction of theout-of-plane field. © 2009 American Institute of Physics. DOI: 10.1063/1.3056139INTRODUCTIONSeveral proposed devices in magnetic recording, sens-ing, and logic depend on fast reliable motion of a domainwall along nanowires.1,2 In a narrow thin magnetic nanowire,the magnetic moments of the material lie in the plane of thewire and are aligned along the long axis. A transverse do-main wall separates the regions of alternating magnetizationlying head to head or tail to tail.3 An external magnetic fieldapplied in the plane of the wire is used to drive the domainwall along the long axis of the wire. It is known that themaximum speed of the domain wall occurs when the appliedfield is equal to the so-called Walker field, typically on theorder of 10–20 Oe.4–6 When the driving field is greater thanthis critical field, an antivortex nucleates inside the domainwall. The antivortex stops the forward propagation of thedomain wall until the vortex travels across the width of thewire. The nucleation of the antivortex decreases the averagedomain wall speed by an order of magnitude. Recent workhas shown that it is possible to suppress the effects of theantivortex by applying an additional magnetic field out of theplane of the wire.7 The out-of-plane OOP field reverses themagnetic moments of the antivortex core which changes thedirection of the gyrovector and leads to the fast ejection ofthe nucleated antivortex.8 Reducing the braking effect of theantivortex leads to fast domain wall motion for all in-planedriving fields greater than the Walker field. This field can beapplied externally or with the addition of a perpendicularlymagnetized underlayer.9The OOP magnetic field must be strong enough to re-verse the magnetic moments in the nucleated antivortex.7 InFig. 1 the average speed of the domain wall is shown as afunction of the OOP magnetic field for an in-plane drivingfield greater than the critical Walker field. Above the criticalOOP field there is a sharp increase in the average speed ofthe domain wall. In the presence of a large OOP field thewall speed approaches the critical speed reached at theWalker field. The inset of Fig. 1 shows the dependence of thecritical field on the cross-section dimensions of the nanowire.The OOP critical field increases with wire thickness. An an-tivortex nucleates when the magnetic moments in the domainwall rotate out of the plane of the wire.7,10 For thin wires thestrong shape anisotropy helps to keep the moments in theplane of the wire. However as the thickness of the wire in-creases, the shape anisotropy decreases and it becomes easierfor the magnetic moments to rotate out of the plane of thewire. An increase in the OOP field is necessary to make upfor the reduction in the shape anisotropy. The larger OOPfield helps to keep magnetic moments aligned in the plane ofthe wire.SIMULATIONThe Landau–Lifshitz LL equation of motion for a mag-netic moment m isaElectronic mail: andrew.kunz@marquette.edu.FIG. 1. Domain wall speed in a 1005 nm2 cross-section wire as a func-tion of out-of-plane magnetic field when driven by a 30 Oe in-plane field. Asharp increase in wall speed is found at a certain OOP critical field. Theinset shows the OOP critical field dependence on the cross-sectional dimen-sions of the wire.JOURNAL OF APPLIED PHYSICS 105, 07D502 20090021-8979/2009/1057/07D502/3/$25.00 © 2009 American Institute of Physics105, 07D502-1mt= − m  H  −Msm  m  H  , 1where  is the gyromagnetic ratio,  is the phenomenologi-cal damping parameter, Ms is the saturation magnetization,and H is the total field experienced by the moment. The firstterm on the right hand side models the precession of themagnetic moments about the local field, and the second termis responsible for rotating the magnetization into the direc-tion of the field. Micromagnetic simulation of the LL equa-tion of motion is used to model the motion of domain wallsin nanowires 5 m in length with rectangular crosssections.11 The thickness 5–20 nm and the width50–300 nm of the wires are varied. The wire is built upfrom identical cubic grains of uniform magnetization, 2.5 or5.0 nm on edge. The fourth order predictor-corrector timestep is less than a picosecond and the damping parameter is 0.008. The materials parameters are those typical of Per-malloy. The in-plane driving field is applied along the +xaxis of the wire that has a magnitude of 30 Oe in all simu-lations presented. A 30 Oe field is greater than the Walkerfield for all wire cross sections simulated so antivorticesshould always nucleate.RESULTS AND ANALYSISAbove the Walker field the nucleation of an antivortexleads to a periodic stepping of the domain wall down thewire. In Fig. 2 the position of the domain wall as a functionof time is presented for three different OOP field strengths.The OOP field is always applied along the +z axis. In theabsence of the OOP field the wall motion is periodic andsymmetric as expected.10,12 The snapshots in Fig. 2 show thetypical domain patterns and the motion of the vortex core.Each of the wall motions plotted begin in state A, and theperiodic motion follows the pattern ABCD before repeating.The grayscale represents the z-component of the magneticmoments and the arrows represent the in-plane magnetiza-tion.The transverse y-direction core speed is shown in Fig.3 as a function of the OOP field. A negative field means thatthe core and the OOP field are aligned antiparallel, and posi-tive means parallel alignment. The transverse speed of thevortex core depends linearly on the strength of the OOP field.We note that while the vortex core crossing time dependslinearly on the OOP field strength; the crossing time is inde-pendent of the width of the wire.13 The combination of Figs.2 and 3 give a complete picture of the core motion. In theabsence of an OOP field and starting with the wall momentsin the −y direction as shown in state A, the precessional termin the LL equation of motion rotates the wall moments out ofthe plane of the wire and into the −z direction. Eventually theantivortex nucleates at the bottom edge of the wire with thecore moments pointing in the −z direction. As the core trav-els upward, it reverses the wall moments behind it, as shownin state B, before exiting at the top edge of the wire.7,10,14The damping term in the LL equation now drives the wall, asshown in state C, along the length of the wire before anotherantivortex nucleates. This time the precessional motionnucleates a core with the magnetic moments aligned in the+z direction and at the top edge of the wire. The core travelsin the downward direction as shown in state D, reversing themagnetization of the domain wall behind it. Once the wallexits at the bottom edge of the wire, the process repeats itselfuntil the wall reaches the end of the wire. The addition of anOOP field less than the critical value does not stop the peri-odic motion, but Fig. 2 shows that there are changes in themotion of the core. When the core moments are aligned inthe direction of the OOP field snapshot D the core movesmore quickly, and when the core moments are antiparallelsnapshot B the core moves more slowly. The width of theplateaus in Fig. 2 show the core crossing time, and the trans-verse core speed is plotted in Fig 3. The alignment of theOOP field and the core moments changes the speed of theFIG. 2. Plot of the domain wall position as a function of time in a 1005 nm2 cross-section wire for three different OOP field strengths. Belowthe critical field and asymmetry in the domain wall motion occurs. Themagnetic structure of the nanowire is presented in the inset with the gray-scale representing the OOP component of the magnetization. The periodicmotion of the domain wall follows the pattern ABCD.FIG. 3. Transverse speed of the antivortex core as a function of OOP fieldstrength. Positive fields correspond to parallel alignment of the field andantivortex core moments. The inset shows the corresponding change in an-tivortex core diameter as a function of the OOP field for a 1005 nm2cross-section wire.07D502-2 Kunz, Breitbach, and Smith J. Appl. Phys. 105, 07D502 2009core. In addition, the domain wall travels further when thecore is going to nucleate antiparallel to the OOP field A→B, and it travels a shorter distance when the alignment isparallel C→D. The total periodicity of the motion remainsrelatively unchanged from the case in which no OOP field isapplied. The OOP field therefore inhibits but does not fullysuppress the nucleation event in the antiparallel case but en-hances it when parallel. As shown in Fig. 2, a larger OOPfield is necessary to recover fast domain wall motion.The inset of Fig. 3 shows that the vortex core dimen-sions are linearly dependent on the alignment of the field andcore moments. The antivortex core is a sharp feature, shownin states B and D in Fig. 2, and we define the diameter of thecore to be the distance over which the z-component of themagnetization varies from the bulk value found in the do-mains and the domain wall. The Zeeman energy, −m ·H ,decreases when the core moments and the field are aligned.This reduction in energy leads to larger vortex cores. Thedomain wall speed is known to depend on the size of thedomain wall and using magnetic fields to change the wallsize is known to change the wall speed.4,15 The same mecha-nism is responsible for the direct relationship between thetransverse core speed and diameter.CONCLUSIONThere is an OOP critical field above which domain wallscan be driven quickly along wires for in-plane fields greaterthan the Walker field where vortex nucleation is important.The vortex core is reversed above the OOP critical field.Below this new critical field the OOP field couples with themagnetic moments of the vortex core. This coupling changesthe size of the core and causes it to move more quicklyacross the wire when the alignment is parallel.ACKNOWLEDEGMENTSThis work was supported by a Research CorporationCottrell College Science Award and the National ScienceFoundation under Grant No. DMR 0706194. Thanks to OlegTchernyshyov for helpful discussions.1S. S. Parkin, M. Hayashi, and L. Thomas, Science 320, 190 2008.2D. A. Allwood, G. Xiong, C. C. Faulkner, D. Atkinson, D. Petit, and R. P.Cowburn, Science 309, 1688 2005.3R. D. McMichael and M. J. Donahue, IEEE Trans. Magn. 33, 4167 1997.4N. L. Schryer and L. R. Walker, J. Appl. Phys. 45, 5406 1974.5Y. Nakatini, A. Thiaville, and J. Miltat, Nature Mater. 2, 521 2003.6G. S. D. Beach, C. Nistor, C. Knutson, M. Tsoi, and J. L. Erskine, NatureMater. 4, 741 2005.7A. Kunz and S. C. Reiff, Appl. Phys. Lett. 93, 082503 2008.8A. A. Thiele, Phys. Rev. Lett. 30, 230 1973.9J.-Y. Lee, K.-S. Lee, and S.-K. Kim, Appl. Phys. Lett. 91, 122513 2007.10D. G. Porter and M. J. Donahue, J. Appl. Phys. 95, 6729 2004.11LLG MICROMAGNETIC SIMULATOR v2.61, 2007 http://llgmicro.home.mindspring.com.12J.-Y. Lee, K.-S. Lee, S. Choi, K. Y. Guslienko, and S.-K. Kim, Phys. Rev.B 76, 184408 2007.13O. A. Tretiakov, D. Clarke, G.-W. Chern, Y. A. Bazaliy, and O. Tcherny-shyov, Phys. Rev. Lett. 100, 127204 2008.14A. Vanhaverbeke, A. Bischof, and R. Allenspach, Phys. Rev. Lett. 101,107202 2008.15A. Kunz and S. C. Reiff, J. Appl. Phys. 103, 07D903 2008.07D502-3 Kunz, Breitbach, and Smith J. Appl. Phys. 105, 07D502 2009

Antivortex Dynamics in Magnetic Nanostripes

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Antivortex Dynamics in Magnetic Nanostripes

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