The field of magnonics aims to employ spin-waves to propagate and process information1,2. Spin-waves offer a host of attractive benefits as data carriers including low heat generation, power consumption3 and coherent coupling to photons4, phonons5 and other magnons6,7,8,9. Functional magnonics has proliferated in recent years, with wide-ranging applications from transistors10 to multiplexers11 and logic gates12. As the complexity of magnonic designs increases, so does the demand for versatile, reconfigurable host systems.

Recently, a family of metamaterials termed reconfigurable magnonic crystals (RMC)13,14,15,16,17 has made strong progress in answering this need. Typically comprising discrete nanopatterned magnetic elements closely-packed in arrays to promote strong dipolar coupling, RMC support multiple microstates and exhibit distinct microstate-dependent magnonic dynamics and spectra with diverse functional benefits. A subset of RMC has emerged based on artificial spin ice (ASI) arrays17,18,19,20,21,22 where geometrical frustration gives rise to a vastly degenerate microstate space that features a long-range ordered ground state23,24 and high-energy ‘magnetic monopole’-like excited states25,26. The potential to leverage these states for their magnonic properties is great and studies into fundamentals of state-spectra correspondence27,28,29,30,31,32,33 have set the scene for a new generation of ASI-based RMC designs. An open problem in the field is developing reliable, versatile and rapid means for microstate access. While ASI possesses a huge range of states, they remain largely unavailable for magnonic exploitation due to state preparation techniques being overly simplistic (for example global-field protocols which may only prepare saturated or randomly demagnetised, unrepeatable states), overly slow (surface-probe microscope nanomagnetic writing techniques24,34,35,36 which may prepare any state but on timescales unsuitable for technological integration) or difficult to realise with current nanofabrication techniques (for example, recently proposed multi-level stripline technique37). In the absence of such techniques, ASI systems have been modified to allow access to an enhanced microstate range using global fields, ‘magnetic charge ice’ which rotates a subset of bars in square ASI to allow global-field preparation of three microstates35,38,39 (types 1–3 as seen in Fig. 1) or bar subset modification via either material40, shape-anisotropy30 or exchange-bias41. The magnetic charge ice case is elegant, but the way in which bars are rotated leads to greater separations between neighbouring elements so that greater density is required to achieve an appreciable interelement coupling required for collective excitations. Moreover, the rotation means different sublattices will in general experience different effective global excitation and bias fields.

Fig. 1: Schematic of width-modified square and high-density square reconfigurable magnonic crystals and their type 1-4 microstates and hysteresis loops.
figure 1

y and x array axes are referred to as ‘ground-state’ and ‘monopole’ orientations throughout this work. a Scanning electron micrograph of the square sample. Bars are 830 nm long, 230 nm (wide-bar) and 145 nm (thin-bar) wide, 20 nm thick with 120 nm vertex gap (bar-end to vertex-centre). b Scanning electron micrograph of the high-density square sample. Bars are 600 nm long, 200 nm (wide-bar) and 125 nm (thin-bar) wide, 20 nm thick with 100 nm vertex gap. cf MOKE hysteresis loops of S sample in ‘ground state’ (c) and ‘monopole’ (d) orientations, HDS sample in ‘ground state’ (e) and ‘monopole’ (f) orientations. Blue points show fully-saturating hysteresis loop, orange points show minor loops with maximum positive field value chosen to prepare sample in type 1 (c, e), type 4 (d) and type 3 (f) states before sweeping back to negative saturation. gj Magnetic force microscope images of type 1–4 microstates. Type 1 and 4 states have inset SEM images showing the relative orientation of Hext to the width-modified subsets required for state preparation. Type 2 and 3 states may be prepared in either ± 90 field orientation. Type 1 and 4 states are often termed ‘ground state’ and ‘monopole’ state in artificial spin ice. kn Magnetic charge dumbbell schematic of type 1–4 microstates.

Here, we present a square ASI with a ‘staircase’-pattern subset of width-modified bars. Shown in Figure 1, this enables preparation of four distinct type 1–4 microstates (Fig. 1b–e, g–j) including the typically elusive ground-state (type 1) and ‘monopole’ states (types 3 and 4). The four states display rich and distinct magnonic spectra with fine control over mode frequency shifting, gap opening and tuning, and number of active modes. Microstate-dependent mode-hybridisation and anticrossings are observed with coupling-strength and gap width tunable via state selection. Selective mode-hybridisation offers reconfigurable mode profile and index control in-field and crucially at remanence.

Results and discussion

Microstate access via width-modification

Samples were designed by taking square ASI and increasing the width of one nanobar subset. Two samples were fabricated, square (S, Fig. 1a) and high-density square (HDS, Fig. 1b), using an electron beam lithography liftoff process and thermal deposition of Ni81Fe19. Sample dimensions were selected such that the wider bar subset may be magnetically reversed via a global-field without thin-bars also reversing from the combination of global-field Hext and local dipolar field Hloc, satisfying Hc2 > Hext + Hloc > Hc1 with Hc1 and Hc2 the wide and thin-bar coercive fields respectively (Hc1 and Hc2 visible in Fig. 1 MOKE loops). This enables preparation of the entire range of ordered, ‘pure’ (i.e. single vertex type across the array) microstates. Arrays comprising identical bars may only access a single pure microstate by saturating with global-field (type 2). The width-modification employed here allows global-field access to four pure states with distinct local-field profiles and corresponding magnonic spectral dynamics. Microstates are shown via magnetic force microscope (MFM) (Fig. 1g–j) and magnetic charge schematics (Fig. 1k–n). The S sample comprises bars of 830 nm × 230 nm (wide-bar), 145 nm (thin-bar) × 20 nm, 120 nm vertex gap (defined bar end to vertex centre). The HDS sample comprises bars of 600 nm × 200 nm (wide-bar), 125 nm (thin-bar) × 20 nm, 100 nm gap.

Bars are widened in alternating y-axis columns (axes defined in Fig. 1a) such that wide-bars may be reversed from a saturated background state (type 2, Fig. 1h, l) without reversing thin-bars. If the global-field Hext is oriented along the y-axis, reversing only wide-bars from a \(\hat{y}\)-saturated state leaves the system in the antiferromagnetic type 1 state (Fig. 1g, k), which forms the ASI ground state with and without width-modification23,42,43. Here the microstate allows the maximum amount of inter-bar dipolar flux-closure and lowest system energy. If Hext is oriented along the x-axis, reversing wide-bars results in the type 4 state (Fig. 1j, n), termed a ‘monopole’ or ‘all-in, all-out’ state43,44,45,46 with four like-polarity magnetic charges at each vertex, highly-repulsive inter-bar dipolar field interactions and maximum system energy. If Hext has any angular misalignment from the width-modified columns, one of the ± 45 wide-bars will experience a higher field along its easy-axis, resulting in that bar reversing at lower Hext. The resulting state with just one of the ± 45 wide-bars reversed is the type 3 state (Fig. 1i, m) with three like-polarity and one opposite polarity magnetic charge per vertex. In experiment there is always some angular misalignment and the array will transition between states 2 and 4 via state 3. The field window in which state 3 exists may be broadened by deliberately increasing angular misalignment. The S array may access type 1–4 states, the HDS array may access states 1-3 but not 4 as the increased Hloc magnitudes arising from smaller inter-bar separation leads to spontaneous reversal of thin-bars from a thin-bar majority charge type 3 to a wide-bar majority type 3 when attempting state 4 access, i.e. Hext + Hloc > Hcthin.

We analyse mode frequencies following the Kittel equation47\(f=\frac{{\mu }_{0}\gamma }{2\pi }\sqrt{{\bf{H}}({\bf{H}}+{\bf{M}})}\) in the k = 0 limit applicable to this work, with γ the gyromagnetic ratio and H = Hext + Hloc. The local dipolar field landscape varies greatly between microstates, with resulting distinct microstate-dependent magnon spectra.

Microstate-dependent magnonic spectra

Broadband FMR spectra were measured using a flip-chip method with samples excited by a coplanar waveguide. Frequency resolution is 20 MHz. For S and HDS samples, spectra were taken with Hext in \(\hat{y}\) (‘ground-state’ orientation, as in Fig. 1a) and \(\hat{x}\) (‘monopole’ orientation). Samples were saturated at Hext = − 1000 mT then swept from -300 mT to 300 mT, above the saturation fields observed in MOKE data to examine spectral effects when shape anisotropy is overcome. Accompanying micromagnetic simulations were performed using MuMax3.

 Figure 2 shows differential FMR spectra for each sample and orientation at ± 300 mT field range (Fig. 2a–e, relative Hext orientation inset) and 0 − 40 mT range (Fig. 2f–j) with corresponding simulated spectra (Fig. 2k–o).

Fig. 2: Differential ferromagnetic resonance spectra of square (S) and high-density square (HDS) samples with corresponding micromagnetic simulations.
figure 2

Peak amplitude occurs at boundary between white and black bands. Samples were saturated in 1000 mT negative field then swept in positive field direction, with relative field orientation indicated in inset scanning electron micrographs. Measurements were performed at room temperature. Fields were swept from ± 300 mT, with full sweeps (ad), 0-40 mT sweeps around the coercive fields (eh) and micromagnetic MuMax3 simulations of the coercive field region (il) presented. Sample geometry and Hext orientation are shown inset. Switching fields are labelled by vertical dashed lines, a and b subscripts refer to separate ± 45 and  45 subset reversal where applicable, type 3- and 3+ refer to thin-bar majority and wide-bar majority type 3 states respectively. From left to right, vertical columns of spectra relate to samples: S (‘ground-state’ orientation), S (‘monopole’ orientation), HDS (‘ground-state’ orientation), HDS (‘monopole’ orientation).

Spectra exhibit two main Kittel-like modes, the lower and higher frequency modes corresponding to bar-centre localised modes in the wide W1 and thin-bars T1 respectively. This correspondence is evidenced by frequency jumps and \(\frac{\partial f}{\partial {\bf{H}}}\) sign inversions indicating bar reversal48 in the low- and high-f modes at Hc1 and Hc2 respectively, matching switching fields observed via MOKE (Fig. 1c–f). Higher relative amplitude of the low-f mode matches the larger sample volume share of the wide-bar, simulated spatial mode-power maps support the mode-bar correspondence. The wide-bar exhibits two higher-index modes W2 and W3, occurring at lower frequency relative to W1 due to the backward-volume wave nature of the modes. Simulated spatial mode profiles are shown in Supplementary Fig. 1. Higher-order modes are expected in the thin-bar and observed in simulation, but fall below the amplitude threshold for experimental detection. In addition to offering two well-defined frequency channels, the different width bar subsets allow clear identification of which subset has reversed or undergone microstate-dependent frequency shifting.

For Hext > 200 mT, thin and wide-bar modes tend to the same frequency as shape-anisotropy is overcome and bar magnetisation rotates from an Ising-like state to lie parallel to Hext. At these Hext, the bar demagnetising fields become negligble and the Kittel equation is dominated by Hext.

At lower fields around Hc1 and Hc2, rich and distinct spectra are observed between samples and orientations. Figure 2e shows S sample spectra in ‘ground-state’ orientation. At Hext = 0 the system is in a negatively-saturated type 2 microstate (Fig. 1h, l), the Mx component of all bars oriented against positive Hext and both modes exhibiting negative \(\frac{\partial f}{\partial {\bf{H}}}\). At Hc1 = 16 mT the wide-bars reverse, its mode jumping 6.2-7.8 GHz and displaying positive \(\frac{\partial f}{\partial {\bf{H}}}\). The thin-bar mode is blueshifted 0.1 GHz at Hc1 due to the change in local dipolar field landscape as the system enters a type 1 microstate (Fig. 1g, k). For Hc1 < Hext < Hc2 the system is in a type 1 state, the two modes exhibiting opposite \(\frac{\partial f}{\partial {\bf{H}}}\) and crossing at Hext = 23mT. Opposing frequency gradients and presence of a mode crossing in this field range afford sensitive mode and gap tunability via Hext. At Hc2 = 29 mT the thin-bars reverse, preparing a type 2 state aligned with Hext and redshifting the wide-bar mode 0.1 GHz via the shift in dipolar field landscape. Above Hc2 both modes exhibit positive \(\frac{\partial f}{\partial {\bf{H}}}\).

Rotating Hex90 accesses the ‘monopole’ orientation. Fig. 2b shows that at high-field saturated states, ‘monopole’ and ‘ground-state’ orientations behave similarly. Around the coercive fields, Fig. 2f shows stark spectral differences between the orientations. While the ‘ground-state’ orientation transitions directly between a type 2 and type 1 state via simultaneous reversal of both wide-bars, the highly-unfavourable type 4 dipolar field landscape separates the wide-bar switching into two distinct reversal events occurring at different fields. At Hext = 13 mT the ± 45 subset of wide-bars better aligned to Hext reverses, placing the system in a ‘thin-bar majority’ type 3 state (Fig. 1i, m) where both thin-bars and a single wide-bar share like-polarity charges. This splits the low frequency mode as half the wide-bars ( ± 45) reverse while the rest (  45) remain aligned against Hext. The reversed wide-bar mode jumps from 6.0-7.7 GHz and exhibits positive \(\frac{\partial f}{\partial {\bf{H}}}\). The unswitched wide-bar mode is blueshifted 0.3 GHz and the thin-bar mode redshifted 0.1 GHz by the type 3 dipolar field landscape. This reduces the gap between unswitched wide and thin-bar modes by 0.4 GHz without modifying the magnetisation state of either bar, demonstrating the degree of spectral control available via microstate engineering. Remaining wide-bars reverse at 20 mT, placing the system in a type 4 microstate (Fig. 1j, n) and unifying the wide-bars in a single 7.5 GHz mode, redshifted 0.1 GHz relative to the already-reversed wide-bar mode. Thin and wide-bar modes now occupy the same frequency, obscuring the expected thin mode blueshift in the experimental data. The mode gap width may be modified by varying the relative bar widths at the fabrication stage, and the overlap here is a consequence of the specific dimensions employed. At Hc2 = 23 mT the thin-bar reverses, placing the system in a type 2 state aligned with Hext and restoring the mode gap.

To demonstrate the spectral control available via array design choices, the HDS sample was fabricated. By reducing bar-length and inter-bar separation, stronger dipolar interactions between bars and greater variation in the dipolar field landscape is achieved, resulting in larger spectral shifts when transitioning state. Fig. 2g shows the HDS ‘ground-state’ orientation, qualitatively matching that of the S sample but with frequency shifts of 0.2 GHz (twice that observed in the S sample) and a broadened type 1 field window due to the increased stability. Fig. 2h shows the HDS ‘monopole’ orientation, again qualitatively matching that of the S sample (with enhanced 0.3 GHz frequency shifts) up to 23 mT where the system transitions from a thin-bar majority type 3 state to a wide-bar majority type 3 rather than type 4. A wide-bar majority type 3 persists between 23-30 mT. At 30 mT the remaining ± 45 thin-bar reverses, causing a 0.3 GHz redshift in the thin-bar mode and transitioning to a type 2 state.

Negative field evolution of microstate-dependent magnonic spectra

So far spectra have been measured while positively sweeping Hext after negative saturation. This allows study of the system as it evolves through a range of microstates, but each microstate is stable in a limited field window. Alternatively, states may be prepared via negatively saturating then applying a microstate-specific positive field (i.e., 22 mT for the S sample type 1 state, Fig. 2e, then recording spectra while negatively sweeping Hext until saturation. This allows mode dynamics to be studied for each microstate over its entire stable field range, revealing additional spectral details not accessed in Fig. 2e–h 0-40 mT sweeps. Field protocols correspond to the orange traces on the Fig. 1c–f MOKE loops.

Figure 3 shows negatively-swept spectra for the S (FMR panels a–d), simulations (e–h) and HDS samples (FMR j–m), simulations n–q) for all microstates and orientations alongside mode extractions (S sample i), HDS (r) allowing state comparison. Figure 3a shows the S sample ‘ground-state’ orientation prepared in a type 1 state at Hext = 22 mT. At 22 mT thin and wide-bar modes occupy a single frequency at 8 GHz. As field is negatively swept, modes exhibit opposite gradient due to opposing wide and thin bar magnetisation, reaching a maximum mode-frequency gap of 3 GHz at -16 mT, after which the wide-bars reverse. This prepares a type 2 state, with a wide-bar frequency jump and thin-bar redshift as observed in the 0-40 mT positive sweeps. The broadly tunable 0-3 GHz gap and wide field-stability window of type 1 state are desirable for functional magnonic systems where mode-frequency gap control is crucial.

Fig. 3: Differential ferromagnetic resonance spectra taken while negatively sweeping Hext after microstate preparation in positive field.
figure 3

Microstates were prepared by −1000 mT saturation then applying the positive field required to reverse the desired bars, hence differing positive field limits for different microstate spectra. ad Experimental spectra for S sample microstates taken in ‘ground-state’ (a, b) and ‘monopole’ (c, d) orientations. eh Simulated S sample microstate spectra for ‘ground-state’ (e, f) and ‘monopole’ (g, h) orientations. i Mode peak-extractions for all S sample microstate-spectra. jl Experimental spectra for HDS sample microstates taken in ‘ground-state’ (j, k) and ‘monopole’ (l) orientations. ‘Monopole’ orientation signal-to-noise is lower due to array-waveguide alignment issues. Modes are still well-resolved and correspond well with simulation. mo Simulated HDS sample microstate spectra for ‘ground-state’ (m, n) and ‘monopole’ (o) orientations. p Mode peak-extractions for all HDS sample microstate-spectra.

Figure 3b shows the ‘ground-state’ orientation S sample prepared in a type 2 state at 10 mT. Sweeping Hext negatively, both modes exhibit a constant gradient and frequency gap of 2 GHz. Figure 3c shows a monopole-orientation type 3 spectra. A 21 mT preparation field reverses half the wide-bars, preparing a thin-bar majority type 3 state. The preparation here is distinct from earlier discussion of type 3 states in the HDS sample, where a well-defined ± 45 subset reverses due to closer alignment to Hext. Here, the Gaussian spread25 of Hc1 throughout the system due to nanofabrication imperfections (termed quenched disorder25,49,50) is leveraged for state-preparation. By selecting a 21 mT field at the centre of the Hc1 distribution, half the wide-bars are reversed and on average the system placed in a type 3 state, with a random distribution of ± 45 wide-bars reversed. While sweeping field back from 21 mT the thin-bar exhibits negative \(\frac{\partial f}{\partial {\bf{H}}}\). The wide-bar mode is split into reversed and unreversed modes exhibiting opposite \(\frac{\partial f}{\partial {\bf{H}}}\) sign. The two modes should cross at 5 mT if no deviation from Kittel-like behaviour is observed. However, the modes are bent away from each other around 5 mT with an anticrossing frequency gap remaining between them. The gap is observed in both experimental and simulated (Fig. 3g) spectra with 0.27 GHz width, and a corresponding 0.30 GHz gap in the HDS type 3 spectra (experimental and simulated in Fig. 3l and p, respectively). Whereas previously discussed mode-frequency shifting occurs due to magnetostatic inter-bar interactions, i.e. the microstate-dependent dipolar field landscapes giving different Hloc values for the Kittel equation, mode anticrossings are an effect of dynamic mode-hybridisation6,8,9,14,31,51. High-resolution anticrossing spectra are shown in Fig. 4 with accompanying discussion below. In addition to the anticrossing the type 3 state offers a high-degree of spectral control, with 3 active modes and tunable mode-gaps.

Fig. 4: Mode-hybridisation and anticrossings.
figure 4

ad Negative-swept field dependent experimental FMR spectra of type 3 states for S and HDS samples in ground-state and ‘monopole’ orientations. Red scatter points are peak extractions of the upper mode branch, blue points extractions of the lower branch. Mode frequency gaps or anticrossings and mode bending in the field range around the crossing point are observed in all samples and orientations. Monopole-orientation crossing points (panels b and d) are offset in positive Hext due to the net Hloc at the vertex, ground state orientation crossings (a and c) are offset at lower magnitude, negative Hext due to the different Hloc profile along this axis. e Simulated spectra of monopole-orientation HDS sample. Anticrossing gap of 0.32 GHz is observed at 4.3 mT. Error bars correspond to frequency range integrated over to produce spatial mode plots shown in f. f Simulated spatial mode-power maps for monopole-orientation HDS sample. Maps I–VI relate to corresponding points labelled on spectra in panel e. High-frequency, single-node mode branch is seen in I-III. Low-frequency, multi-node branch is IV–VI. g Simulated type 1 spectra of ground-state orientation HDS sample. Crossing occurs at 24 mT with no observable gap. Error bars correspond to frequency range integrated over to produce spatial mode plots shown in h. f Simulated spatial mode-power maps for ground-state orientation type 1 HDS sample. Maps I–V relate to corresponding points labelled on spectra in panel e. Mode-hybridisation is not observed, with matching profile pairs I and V, IV and III.

 Figure 3d shows the type 4 state, prepared at 22 mT. Qualitatively the spectra resembles that of the type 1 state but modes exhibit enhanced separation due to different local dipolar field landscape and are redshifted relative to type 1. This is best visualised through peak extractions shown in Fig. 3i. 0.4 and 0.2 GHz mode gaps at 22 mT are observed for type 4 and type 1 states respectively, along with a 0.35 GHz blueshift of the type 1 wide mode relative to type 4 demonstrating the fine control available. At −12 mT one ± 45 subset of wide-bars reverses, preparing a type 3 state with accompanying mode shifts and wide-bar mode-splitting. The remaining wide subset reverses at −16 mT, preparing a type 2 state.

The HDS sample exhibits qualitatively similar behaviour to the S sample with increased magnitude microstate-dependent frequency shifts due to stronger inter-element interaction. Figure 3j shows the ‘ground-state’ orientation HDS sample prepared in a type 1 state at 30 mT. Here a 0-3.6 GHz mode gap is observed over a −12–30 mT field range. Figure 3k shows a type 2 state prepared at 16 mT, exhibiting a constant 2 GHz gap across the field sweep. Figure 3l shows the system in a thin-bar majority type 3 state at 21 mT. The reversed and unreversed wide-bar modes exhibit opposite gradient with a 7.3 GHz crossing at 6 mT.

Microstate-dependent mode hybridisation and anticrossings

In the type 3 spectra (Fig. 3c, g, l and p), where reversed and unreversed wide-bar modes approach a single frequency they do not overlap. The modes instead bend away from a Kittel-like form as they approach, leaving an anticrossing gap9,31,51,52,53 which has been predicted to occur in ASI due to a microstate-dependent band structure31. Figure 4 shows the anticrossing region in type 3 microstates. Samples were prepared in type 3 states in ground-state and monopole orientations, spectra measured while negatively-sweeping field. Mode-bending and anticrossings are exhibited in all experimental spectra (Fig. 4a–d) and corresponding simulations (Fig. 4f–h). Experimental spectra show anticrossing gaps of ΔS,GS = 0.27 GHz, ΔS,monopole = 0.27GHz, ΔHDS,GS = 0.22 GHz, ΔHDS,monopole = 0.3 GHz.

Simulated spatial mode-power maps (Fig. 4f) show this effect occurs due to mode-hybridisation between reversed and unreversed wide-bars, causing the two modes to act like distinct upper and lower frequency v-shaped branches (red and blue peak extraction points respectively in experimental spectra) rather than diagonally intersecting Kittel-like modes. The upper-branch mode profile shows a single-node bulk mode, localised in the reversed bar at fields below the crossing point and the unreversed bar at fields above the crossing. The lower-branch profile shows a double-node bulk mode, localised in the unreversed bar at fields below crossing and vice-versa. At the crossing point, the single-node bulk mode appears in both wide-bars at the upper-branch frequency and the multi-node mode appears in both wide-bars at the lower-branch frequency. The field at which anticrossings occur may be modified by rotating the sample between ground-state and monopole-orientations. The two orientations have different net Hloc values along the Hext-axis due to broken microstate symmetry and resultingly crossings occur at different fields, ground-state at -1 mT (-1 mT), ‘monopole’ at 3 mT (5 mT) in S (HDS) samples. The antiferromagnetic macrospin ordering in type 3 states is crucial for mode-hybridisation. The difficulty in preparing such antiferromagnetic states is a key barrier to observing dynamic coupling effects such as anticrossings, and a key strength of the microstate-access protocol presented here.

The microstate control demonstrated allows tailoring of spectra such that modes may also cross with no resolvable anticrossing. In type 1 states (Fig. 1g, k), crossings are observed between thin and wide-bar modes with no observable gap or deviation from Kittel-like behaviour. Simulated spectra of the crossing point (Fig. 4g) show no anticrossing gap and spatial power maps (Fig. 4h) show a single-node bulk mode throughout the type 1 field range. While the type 1 state exhibits antiferromagnetic order between the thin and wide bars, it occurs at weaker effective interaction than type 3 states as the wide-thin bar vertex separation and dipolar-coupling are reduced relative to the type 3 wide-wide bar case. The lack of a resolvable type 1 anticrossing is testament to the sensitivity of dynamic coupling phenomena to interaction strength. Supplementary Fig. 2 shows simulated 0–10 GHz spectra of the HDS sample (‘monopole’ orientation) in a type 3 state with 0–3 GHz edge modes present and spatial magnetisation profiles of the nanoisland edges. Realignments of the static edge magnetisation occur at −1.5 mT and −6.5 mT for the wide and thin bars respectively, while the anticrossing occurs at 5 mT. As such, static magnetisation realignments are unlikely to be involved in the observed mode-hybridisation.

We have demonstrated that introducing a width-modified sublattice to ASI permits rapid, scalable and reconfigurable control over rich and diverse spectral features. This approach offers an attractive addition to the host of spectral and microstate control methodologies, requiring only widely-available global-field and nanofabrication protocols. The state-dependent spectra observed suggest microwave-assisted state preparation54,55,56,57 as a promising direction for integrated read-write functionality.

The magnitude and diversity of microstate-dependent mode and gap control exhibited invite a host of functional applications including tunable microwave filters and enable further study of how spin-wave characteristics and band structure of nanomagnetic systems may be employed in magnonic logic58 and neuromorphic devices59. In particular, the observation of previously elusive microstate-dependent mode-hybridisation and anticrossings suggests a magnonic device which may reconfigurably transmit or reflect spin-waves depending on its state. In this regard we emphasise that anticrossing behaviour depends only on the microstate and does not require width-modification except as a means for microstate access. As state-preparation techniques develop, we expect mode-hybridisation to become observable and exploitable in other artificial spin systems.


Simulations were performed using MuMax3. To maintain field sweep history, ground state files are generated in a separate script and used as inputs for dynamic simulations. S sample dimensions are; wide: 800 by 230 by 20 nm, narrow: 800 by 130 by 20 nm and lattice parameter: 1120 nm (gap = 160 nm). HDS sample dimensions are; wide: 600 by 200 by 20 nm and narrow: 600 by 130 by 20 nm and lattice parameter: 800 nm (gap = 100 mn). Perturbation of dimensions from SEM images were introduced to more accurately reproduce both static and dynamic magnetisation behaviour. Material parameters for NiFe used are; saturation magnetisation, Msat = 750 kA/m, exchange stiffness. Aex = 13 pJ and damping, α = 0.001 All simulations are discretized with lateral dimensions, cx,y = 5 nm and normal direction, cz = 10 nm and periodic boundary conditions applied to generate lattice from unit cell. A broadband field excitation sinc pulse function is applied along z-direction with cutoff frequency = 20 GHz, amplitude = 0.5 mT. Simulation is run for 25 ns saving magnetisation every 25 ps. Static relaxed magnetisation at t = 0 is subtracted from all subsequent files to retain only dynamic components, which are then subject to a FFT along the time axis to generate a frequency spectra. Power spectra across the field range are collated and plotted as a colour contour plot with resolution; Δf = 40 MHz and Δμ0H = 1 mT. Spatial power maps are generated by integrating over a range determined by the full width half maximum of peak fits and plotting each cell as a pixel whose colour corresponds to its power. Each colour plot is normalised to the cell with highest power. High-resolution simulations performed for Fig. 4 have lower damping, α = 0.0001, and are run for 100 ns saving every 50 ps. This produces colour plots with resolution; Δf = 10 MHz and Δμ0H = 0.2 mT. Hext is offset from the array \(\hat{x},\hat{y}\)-axes by 1 to better match experiment. Lowering alpha reduces mode linewidth and allows for better resolution of mode behaviour particularly when multiple modes are present in close frequency proximity, as in the anticrossing case.

Samples were fabricated via electron-beam lithography liftoff method on a Raith eLine system with PMMA resist. Ni81Fe19 (permalloy) was thermally evaporated and capped with Al2O3. A ‘staircase’ subset of bars was increased in width to reduce its coercive field relative to the thin subset, allowing independent subset reversal via global field.

Ferromagnetic resonance spectra were measured using a NanOsc Instruments cryoFMR in a Quantum Design Physical Properties Measurement System. Broadband FMR measurements were carried out on large area samples ( ~ 2 × 2mm2) mounted flip-chip style on a coplanar waveguide. The waveguide was connected to a microwave generator, coupling RF magnetic fields to the sample. The output from waveguide was rectified using an RF-diode detector. Measurements were done in fixed in-plane field while the RF frequency was swept in 20 MHz steps. The DC field was then modulated at 490 Hz with a 0.48 mT RMS field and the diode voltage response measured via lock-in. The experimental spectra show the derivative output of the microwave signal as a function of field and frequency. The normalised differential spectra are displayed as false-colour images with symmetric log colour scale.

Magnetic force micrographs were produced on a Dimension 3100 using commercially available normal-moment MFM tips.

MOKE measurements were performed on a Durham Magneto-Optics NanoMOKE system. The laser spot is approximately 20 μm diameter. The longitudinal Kerr signal was normalised and the linear background subtracted from the saturated magnetisation. The applied field is a quasistatic sinusoidal field cycling at 11 Hz and the measured Kerr signal is averaged over 300 field loops to improve signal to noise.