Efficient Excitation of High-Frequency Exchange-Dominated Spin Waves in Periodic Ferromagnetic Structures

Aryan Navabi, Cai Chen, Anthony Barra, Mohsen Yazdani, Guoqiang Yu, Mohammad Montazeri, Mohammed Aldosary, Junxue Li, Kin Wong, Qi Hu, Jing Shi, Gregory P. Carman, Abdon E. Sepulveda, Pedram Khalili Amiri, and Kang L. Wang

Phys. Rev. Applied 7, 034027 – Published 28 March 2017

Abstract

Spin waves are of great interest as an emerging solution for computing beyond the limitations of scaled transistor technology. In such applications, the frequency of the spin waves is important as it affects the overall frequency performance of the resulting devices. In conventional ferromagnetic thin films, the magnetization dynamics in ferromagnetic resonance and spin waves are limited by the saturation magnetization of the ferromagnetic (FM) material and the external bias field. High-frequency applications would require high external magnetic fields which limit the practicality in a realistic device. One solution is to couple microwave excitations to perpendicular standing spin waves (PSSWs) which can enable higher oscillation frequencies. However, efficient coupling to these modes remains a challenge since it requires an excitation that is nonuniform across the FM material thickness and current methods have proven to be inefficient, resulting in weak excitations. Here, we show that by creating periodic undulations in a 100-nm-thick ${Co}_{40} {Fe}_{40} B_{20}$ layer, high-frequency PSSWs ( $> 20 GHz$ ) can be efficiently excited using micrometer-sized transducers at bias fields below 100 Oe which absorb nearly 10% of the input rf power. Efficient excitation of such spin waves at low fields may enable high-frequency spintronic applications using exchange-dominated magnetic oscillations using very low external magnetic fields and, with design optimizations, can bring about alternative possibilities in the field.

Received 20 December 2016

DOI:https://doi.org/10.1103/PhysRevApplied.7.034027

Physics Subject Headings (PhySH)

Ferromagnetism Spin waves Spintronics

Ferromagnets

Ferromagnetic resonance

Condensed Matter, Materials & Applied Physics

Authors & Affiliations

Aryan Navabi^1,*, Cai Chen², Anthony Barra², Mohsen Yazdani¹, Guoqiang Yu¹, Mohammad Montazeri¹, Mohammed Aldosary³, Junxue Li³, Kin Wong¹, Qi Hu¹, Jing Shi³, Gregory P. Carman², Abdon E. Sepulveda², Pedram Khalili Amiri¹, and Kang L. Wang^1,†

¹Department of Electrical Engineering, University of California, Los Angeles, California 90095, USA
²Mechanical and Aerospace Engineering Department, University of California, Los Angeles, California 90095, USA
³Department of Physics and Astronomy, University of California, Riverside, California 92521, USA

^*Corresponding author. aryan.n@ieee.org
^†wang@ee.ucla.edu

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Vol. 7, Iss. 3 — March 2017

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Images

Figure 1
$S_{11}$ parameters of measured flat and undulating ${Co}_{40} {Fe}_{40} B_{20}$ layers. (a) Cross-sectional SEM image shows that the 100-nm-thick ${Co}_{40} {Fe}_{40} B_{20}$ layer deposited on the undulating substrate inherits the topography of the substrate. (b) Schematic of the spin-wave device. An external magnetic field $H_{bias}$ with a dynamic magnetic field originating from an rf current in the CPW is used to excite spin waves. (c) Measured $S_{11}$ parameter of 100-nm-thick flat ${Co}_{40} {Fe}_{40} B_{20}$ layer. (d) Measured data for the MSSW mode (circles) along with fitted curve (solid line) using the MSSW dispersion relation [Eq. (1)]. (e) Measured $S_{11}$ parameter of 100-nm-thick undulating ${Co}_{40} {Fe}_{40} B_{20}$ layer with topography shown in Fig. 1. (f) Measured data for the MSSW and PSSW modes, circles and squares, respectively, along with fitted curves using the MSSW dispersion relation [Eq. (1)], bottom solid line, and PSSW dispersion relation [Eq. (2)], top dashed line.
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Figure 2
$S_{11}$ parameters of measured flat and undulating YIG layers. (a) Measured $S_{11}$ parameter of 100-nm-thick flat YIG layer. (b) Measured data for the MSSW mode (circles) along with fitted curve (solid line) using the MSSW dispersion relation [Eq. (1)]. (c) Measured $S_{11}$ parameter of 100-nm-thick undulating YIG layer with topography shown in Fig. 1. (d) Measured data for the MSSW and PSSW modes, circles, and squares, respectively, along with fitted curves using the MSSW dispersion relation [Eq. (1)], bottom solid line, and PSSW dispersion relation [Eq. (2)], top dashed line.
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Figure 3
Micromagnetic model geometry and simulated $S_{11}$ parameters for the undulating and flat ${Co}_{40} {Fe}_{40} B_{20}$ and YIG FM’s. (a) SEM image detailing the as-fabricated undulating FM structure which is approximated for the model geometry. (b) The FDTD model approximation to the structure in (a), most importantly showing matching out-of-plane thickness dimensions (where the PSSWs form). (c) A comparison is made between the frequency-dependent susceptibility of flat and undulating ${Co}_{40} {Fe}_{40} B_{20}$ for a $z$ -directed 1000-Oe bias field. (d) The same comparison made in (c) for ${Co}_{40} {Fe}_{40} B_{20}$ is made for YIG. Note the comparatively smaller gap between resonances for YIG. (e) The absorption spectrum is shown for flat ${Co}_{40} {Fe}_{40} B_{20}$ . Gray line indicates peaks in experimentally measured absorption, whereas blue circle markers indicate the corresponding simulated peaks. (f) The measured (solid and dashed lines) and simulated (red circle and square markers) absorption spectrum for undulating ${Co}_{40} {Fe}_{40} B_{20}$ . (g) The comparison between experimental and simulated absorption is made for flat YIG. (h) The same comparison is made as in (f),(g), but for undulating YIG.
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Figure 4
The $m_{y}$ component is plotted structure wide while being driven at resonant frequencies in a $z$ -directed 1000-Oe bias field. (a)–(c) A uniform mode excitation is generated at 12.4 GHz in the structure’s left-sloped region. In (a) the left-sloped region is red, indicating ${\tilde{m}}_{y} = 1$ , in (b) it averages to 0, so ${\tilde{m}}_{y} \approx 0$ , and in (c) it is red, so ${\tilde{m}}_{y} = 1$ again. Since each sloped region has a constant color, the oscillations are in phase, and thus showing the dynamics of the fundamental mode. (d)–(f) The PSSW mode is excited in the left-sloped region by driving it externally at 24 GHz. (d) shows a red-blue-red profile through the thickness of the left-sloped region, whereas (f) shows a blue-red-blue profile. The inlay in (f) indicates that this profile (cross section at solid line) corresponds to a sinusoidally shaped PSSW mode.
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Figure 5
Frequency-dependent linewidth of the flat (squares) and undulating (circles) ${Co}_{40} {Fe}_{40} B_{20}$ layer. Equation (3) is used to fit the data (solid lines). The measurements show a smaller offset, and thus a lower extrinsic damping, for undulating samples, in this case, 60.1 Oe, while for the flat sample it is determined to be 96.3 Oe. The fitted line for the undulating sample is also smaller and it corresponds to a Gilbert damping value of 0.0246, whereas the Gilbert damping for the flat sample is estimated to be 0.0319.
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Figure 6
Efficiency of PSSW excitation. (a) rf power absorbed by undulating ${Co}_{40} {Fe}_{40} B_{20}$ derived from $S_{11}$ parameters at bias fields of 80 Oe (blue dashed line) and 500 Oe (red solid line) show the absorption of MSSW and PSSW modes. (b) The orange squares show the amount of rf power absorbed by the PSSW mode at bias fields ranging from 80 to 1990 Oe. The data represent the local maximum of the PSSW mode (center frequency) and show a maximum absorption of nearly 10% at bias fields below 100 Oe. Relative excitation efficiency, shown by blue circles, is defined as the ratio of the peak power absorbed by at the PSSW center frequency normalized by the peak power absorbed at the MSSW center frequency. The ${Co}_{40} {Fe}_{40} B_{20}$ layer shows excitation efficiency of 20% at low bias fields.
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