The problem of quantum tunnelling of a particle through a potential barrier higher than the particle energy is one of the fundamental problems in quantum mechanics1,2,3,4. More than half a century ago Hartman considered analytically tunnelling of a Gaussian wave packet through a rectangular potential barrier of thickness L in metal/insulator/metal junctions5. He derived a formula for the group delay τgr, i.e. the time in which the incident packet travels from the first border of the barrier at x = 0 to the second one at x = L. He concluded that the group delay τgr saturates with increasing barrier thickness, which means that for thick barriers the group delay is shorter than the time required by the packet to traverse the distance L in the corresponding uniform (no barrier) material. This phenomenon is known as the Hartman effect (HE).

However, tunnelling is a wave phenomenon which refers to various kinds of waves, including also wave functions of quantum particles. In general, the tunnelling takes place when the wave passing through the barrier has the form of exponentially evanescent function, and then continues the propagation as an ordinary wave (in oscillatory form) with reduced amplitude and shifted phase. The Hartman’s paper initiated a huge activity in different fields: including (i) tunnelling of electromagnetic Gaussian wave packets in various structures like photonic crystals (see, for example, review articles4,6,7,8,9,10,11,12 and research papers7,13,14,15,16), (ii) tunnelling of acoustical and optical phonons17,18, and (iii) tunnelling of electrons in graphene19,20,21,22,23. For all types of the above mentioned waves, the saturation of group delay with increasing barrier width is observed in tunnelling processes. This feature leads to a counter-intuitive conclusion on an unlimited increase of propagation speed of tunnelling wave packets. This paradox was the subject of intensive scientific debate24 and was explained using the arguments referring to a reshaping of the wave packets25 or to the saturation of energy deposition within the barrier26.

The HE was not studied yet in the case of spin waves (SWs), although the effects related to tunnelling, trapping and mastering of propagation time or velocity for SWs in non-uniform magnetic structures have been already investigated theoretically and experimentally. Most of the experimental studies were performed for dipolar SWs in structures based on yttrium- iron garnet (YIG) or on permalloy. Tunnelling of SW was investigated experimentally in YIG stripes with a single27 (or double28) barrier formed by the Oersted field or in YIG film with a mechanical gap29. There are also reports which show that the group delay or group velocity for SWs in periodic structures can be significantly changed in comparison to those in homogeneous systems30,31,32,33.

In this paper we consider HE for SWs tunnelling through a barrier in a thin magnetic film with perpendicular magnetic anisotropy (PMA). We restrict our considerations to an exchange-dominated region of the spin wave spectrum. We demonstrate theoretically the saturation of the group delay for exchange SWs with increasing width of the barrier, which is an evident signature of HE. The barrier can be created by a local increase of the internal field, which can be caused by a change (increase) of the magnetocrystalline anisotropy within the barrier. Such a barrier can be formed, for instance, using a material with anisotropy higher than that in the remaining (left and right) parts of the junction (referred to in the following as matrix). However, to reduce spin wave scattering at the barrier/matrix interfaces, one can take a uniformly magnetized thin film of a material with low damping, and then, with etching techniques, fabricate a narrow stripe of reduced thickness. By covering the film with an insulating material, one can induce an interface anisotropy, which in a narrow stripe can be different (enhanced) from that in the other parts of the structure. Indeed, for a layer (up to a few nanometers thick) the main contribution to the effective magnetic anisotropy originates from surfaces and/or interfaces, which grows with decreasing layer thickness. More details on the system proposed for experimental investigations of HE are given in the next section.

For dipolar spin waves we can form the barrier in a few other ways. If we consider the magnetic stripe of high magnetization saturation surrounded by two magnetic half-planes made of material of lower magnetization saturation then, in the range between FMR frequencies of this two materials, the spin wave tunnelling can be observed – the Demon-Eshbach modes will be evanescent in the barrier (stripe) and oscillating in the matrix (surrounding material). We suspect that for such system the Hartman effect should be also observed. The other the magnonic systems in which the Hartman effect is expected to be found are the structures with air gaps where the exponentially decaying magnetostatic potential (and associated dynamic demagnetizing field) can couple the spin wave dynamics across the air gap. The magnonic systems operating in the dipolar regime are, in most cases, much easier for fabrication than the extremely small systems working in exchange regime. However, the theoretical description dipolar system is more challenging. Therefore we decided to start, in this paper, from the theoretical and numerical studies of Hartman effect for exchange waves.

The paper is organized as follows. The system under consideration is described in the section “The Model”. In the next section, we present a theoretical description. In this section we discuss the propagation of exchange SWs in the case of spatially dependent anisotropy field. We also outline the theoretical basis of the HE for SWs. Numerical results and their discussion are presented in the subsequent section. The last section contains the summary and final conclusions. The manuscript is supplemented by the discussion of boundary conditions for SWs in exchange regime and technical details concerning the derivation of the transmissivity function.

The Model

The system under consideration, presented schematically in Fig. 1a, is planar. Both external magnetic field H0 and effective anisotropy field Ha(x) are oriented out-of-plane. We assume a one-dimensional magnetic barrier in the form of a stripe region, in which (for 0 < x < L) the effective anisotropy field Ha(x) is increased. The barrier is rectangular, i.e. Ha changes abruptly at x = 0 and x = L, see Fig. 1b. We also assume that the magnetization MS and exchange length λex in the barrier region are changed (reduced) in reference to the matrix regions (x < 0 and x > L), see Fig. 1c.

Figure 1
figure 1

Schematic of the system under consideration. (a) The exemplary structure has the form of a ferromagnetic layer made of a low-damping material (CoFeB) with an out-of-plane magnetic anisotropy induced by the interface with the oxide layer (MgO) deposited on top of the ferromagnetic layer. The groove in the ferromagnetic layer makes the effective anisotropy field Ha higher, forming the barrier (b) due to a larger contribution of the CoFeB/MgO interface anisotropy to Ha. The change in thickness of the magnetic layer can also modify other material parameters (c): saturation magnetisation MS and exchange length λex. In the calculations we used a simplified model with abruptly changing material parameters (solid lines). We also assumed that the material parameters at the interfaces between the barrier and matrix (MS,mb, λex,mb) can be different from the bulk parameters, and can correspond to the weak (W) or natural (N) exchange coupling between the barrier and the matrix.

Thickness of the magnetic layer is much smaller than the considered wavelength of SWs and also smaller than the width of the barrier L. This allows to neglect the spatial changes of spin wave amplitude across the magnetic layer (regardless of the partial pinning which exists due to the interfacial anisotropy Ki between the magnetic layer and nonmagnetic overlayer). To simplify our analysis, we investigate SWs propagating perpendicularly to the barrier only, which effectively reduces the problem to the one-dimensional one.

To take into account the in-plane inhomogeneity of the magnetic material, which in real systems can be observed at the interfaces between the matrix and barrier, we introduce the exchange coupling at these interfaces as an additional parameter of our model. The strength of this exchange coupling is important for determining the interfacial boundary conditions for SWs. These boundary conditions significantly influence the phase factor of the transmissivity T(ω)34,35,36,37, which, in turn, is crucial for the determination of the group delay τgr(ω) of SWs tunnelling (propagating) through (over) the barrier24. Therefore, one can expect that the HE (i.e. saturation of τgr with increasing width of the barrier L) is sensitive to a particular formulation of the boundary conditions for SWs.

For a prospective experimental realization of the considered system we need a material characterized by a high out-of-plane anisotropy field, which additionally ensures low SW damping. A suitable system with PMA is a thin CoFeB layer covered with MgO. The effect of PMA induced at the CoFeB/MgO interface is well known and was already used in spintronics for fabrication of magnetic tunnel junctions of reduced dimensions38. The interfacial anisotropy Ki depends critically on the crystalline structure and bonding at the CoFeB/MgO interfaces. It grows initially with increasing thickness of the MgO layer and then decreases for larger thicknesses, when crystalline MgO starts to form39. For positive values of the energy density (effective anisotropy) \(K={K}_{i}/{t}_{{\rm{CoFeB}}}-{\mu }_{0}{M}_{{\rm{S}}}^{2}/2\), the magnetic easy-axis is oriented out-of-plane and the system is magnetized perpendicularly in the absence of an external field. Thus, by appropriate tuning of the MgO thickness and of the CoFeB thickness (tCoFeB), one can increase the effective anisotropy inside the stripe region and form the barrier (see Fig. 1).

In the following sections we will consider the propagation of exchange SWs in a nonuniform profile of effective (out-of-plane) anisotropy field Ha = 2Ki/(μ0MStCoFeB) − MS, additionally shifted by a spatially homogeneous external field H0 (applied in the same direction). We will show that the field H = Ha(r) + H0 can be treated as a counterpart of electrostatic potential V(r) for electronic waves. In the magnetic barrier, where the spin wave frequency ω fulfils the condition γμ0ω < H0 + Ha(r), the spin wave profile has evanescent character, typical for tunnelling of electronic waves of energy E < V(r). We will exploit this formal similarity of electronic waves and exchange SWs to discuss HE for magnonics.

Theoretical description

In order to discuss HE for exchange dominated the SWs, we start from the derivation of an analytic formula for the transmissivity function T(ω) through a magnetic barrier embedded in a magnetic matrix, taking into account different types of boundary conditions at the barrier/matrix interfaces. Then, we derive the formula for the group delay τgr for spin wave packet tunnelling (propagating) through (over) the magnetic barrier. Finally, we discuss the HE for exchange dominated SWs by analyzing the formula for group delay in the limit of wide barriers.

Exchange spin waves in spatially dependent anisotropy field

In general, the magnetization dynamics in a magnonic system is described by the Landau-Lifshitz equation, which has the following form in the absence of damping:

$$\frac{\partial {\boldsymbol{M}}({\boldsymbol{r}},t)}{\partial t}=-\,\gamma {\mu }_{0}{\boldsymbol{M}}({\boldsymbol{r}},t)\times {{\boldsymbol{H}}}_{{\rm{eff}}}({\boldsymbol{r}},t),$$

where M and Heff stand for the magnetization and the effective magnetic field, respectively, and γ is the gyromagnetic ratio. We consider a system in which the SWs of short wavelengths propagate in a magnetic layer with spatially varying (along with the x-direction) material parameters: saturation magnetization MS(x), magnetic anisotropy Ha(x), and exchange length λex(x). We assume that the effective field, Heff = H0 + Ha + Hex, includes the contributions from a uniform static external magnetic field H0 = [0, 0, H0], static and spatially dependent effective anisotropy field Ha(x) = [0, 0, Ha(x)], and the dynamical term due to the exchange interaction between magnetic moments, Hex(x, t). The latter term can be written as40:

$${{\boldsymbol{H}}}_{{\rm{ex}}}(x,t)=\nabla {\lambda }_{{\rm{ex}}}^{2}(x)\nabla {\boldsymbol{M}}(x,t),$$

where the magnetization M(x, t) precesses around the effective field Heff, M(x, t) ≈ [mx(x)eiωt, my(x)eiωt, MS].

When considering the propagation of SWs in the x-direction (normal to the barrier), the linearized Landau-Lifshits equation can be written in the form:

$$\begin{array}{c}i\frac{\omega }{\gamma {\mu }_{0}}{m}_{x}(x)={M}_{{\rm{S}}}(x)\frac{\partial }{\partial x}{\lambda }_{{\rm{ex}}}^{2}(x)\frac{\partial }{\partial x}{m}_{y}(x)-{m}_{y}(x)(\frac{\partial }{\partial x}{\lambda }_{{\rm{ex}}}^{2}(x)\frac{\partial }{\partial x}{M}_{{\rm{S}}}(x)+{H}_{0}+{H}_{{\rm{a}}}(x)),\\ i\frac{\omega }{\gamma {\mu }_{0}}{m}_{y}(x)=-\,{M}_{{\rm{S}}}(x)\frac{\partial }{\partial x}{\lambda }_{{\rm{ex}}}^{2}(x)\frac{\partial }{\partial x}{m}_{x}(x)+{m}_{x}(x)(\frac{\partial }{\partial x}{\lambda }_{{\rm{ex}}}^{2}(x)\frac{\partial }{\partial x}{M}_{{\rm{S}}}(x)+{H}_{0}+{H}_{{\rm{a}}}(x))\mathrm{.}\end{array}$$

Substituting: m+(x) = mx(x) + imy(x) and m(x) = mx(x) − imy(x) we can write Eq. (3) in the following, more compact form:

$$-\frac{d}{dx}{\lambda }_{{\rm{ex}}}^{2}(x)\frac{d}{dx}{m}_{\pm }(x)+v(x){m}_{\pm }(x)={M}_{{\rm{S}}}^{-1}(x)(\pm \frac{\omega }{\gamma {\mu }_{0}}){m}_{\pm }(x),$$


$$v(x)={M}_{{\rm{S}}}^{-1}(x)({H}_{0}+{H}_{a}(x)+\frac{d}{dx}{\lambda }_{{\rm{ex}}}^{2}(x)\frac{d}{dx}{M}_{{\rm{S}}}(x))\mathrm{.}$$

Equation (4) has the mathematical form of Sturm-Liouville equation, and therefore it possesses the properties of other differential equations of a similar kind (e.g. of the Schrödinger equation). One can identify \({\lambda }_{{\rm{e}}{\rm{x}}}^{2}(x)\) and v(x) as counterparts of the inverse effective mass and the effective potential, respectively. The last term in Eq. (5) contributes to the effective potential v(x) only at the interfaces, at which the material parameters (\({\lambda }_{{\rm{ex}}}^{2}\), MS) change. The formal similarity of Eq. (4) to Schrödinger equation allows one to expect the HE for exchange SWs tunnelling through a barrier, as well.

To find the solution of Eq. (4) in the whole system (see Fig. 1), one has to match the solutions in homogeneous materials of the barrier and of the surrounding medium (matrix). For the barrier and matrix one can write Eq. (4) for m+ as:

$$-{\tilde{M}}_{{\rm{S}},{\rm{\alpha }}}{\lambda }_{{\rm{ex}},\alpha }^{2}\frac{{d}^{2}}{d{x}^{2}}{m}_{+}(x)+(1+{\tilde{H}}_{{\rm{a}},\alpha }){m}_{+}(x)={\rm{\Omega }}\,{m}_{+}(x),$$

where α = {m, b} refers to the matrix (m) or barrier (b), respectively. The exchange lengths λex,m in the matrix and λex,b in the barrier are measured in the units of spatial coordinate x. In turn, \({\tilde{M}}_{{\rm{S}},\alpha }\) and \({\tilde{H}}_{{\rm{a}},\alpha }\) denote the dimensionless saturation magnetization and effective anisotropy field, respectively, for the matrix or barrier:

$${\tilde{M}}_{{\rm{S}},\alpha }=\frac{{M}_{{\rm{S}},\alpha }}{{H}_{0}},{\tilde{H}}_{{\rm{a}},\alpha }=\frac{{H}_{{\rm{a}},\alpha }}{{H}_{0}},$$

whereas Ω is the dimensionless frequency:

$${\rm{\Omega }}=\frac{\omega }{\gamma {\mu }_{0}{H}_{0}}\mathrm{.}$$

The general solution of Eq. (6) takes the form:

$${m}_{+}(x)={C}_{1}{e}^{i{k}_{\alpha }x}+{C}_{2}{e}^{-i{k}_{\alpha }x},$$

where C1 and C2 are certain integration constants, while kα is the wave number which can be written in the form:

$${k}_{\alpha }({\rm{\Omega }})={\lambda }_{\mathrm{ex},\,\alpha \,}^{-1}{\tilde{M}}_{{\rm{S}},\alpha }^{-\frac{1}{2}}\sqrt{{\rm{\Omega }}-(1+{\tilde{H}}_{{\rm{a}},\alpha })}\,.$$

Transmissivity and group delay

Let’s consider now the incident SW \({e}^{i({k}_{{\rm{m}}}x+{\rm{\Omega }}t)}\) of frequency Ω > 1 + \({\tilde{H}}_{{\rm{a}},{\rm{m}}}\), propagating from the left side (x < 0) towards the barrier. Here, time t is given in the units of (H0γμ0)−1. The wave reflected from the barrier can be written as \(R\,{e}^{i(-{k}_{{\rm{m}}}x+{\rm{\Omega }}t)}\), where R is a complex amplitude. In the barrier region (0 < x < L), the corresponding solution takes the form of the wave combination given in Eq. (9), \(({C}_{1}{e}^{i{k}_{{\rm{b}}}x}+{C}_{2}{e}^{-i{k}_{{\rm{b}}}x}){e}^{i{\rm{\Omega }}t}\), where the evanescent solutions (with real exponents ±ikb) appear in the tunnelling regime, i.e. for 1 + \({\tilde{H}}_{{\rm{a}},{\rm{m}}}\) < Ω < 1 + \({\tilde{H}}_{{\rm{a}},{\rm{b}}}\). In turn, the transmitted SW \(T\,{e}^{i({k}_{{\rm{m}}}x+{\rm{\Omega }}t)}\) is observed on the opposite side of the barrier (for x > L) with the complex amplitude T.

The transmissivity T(Ω, L) can be obtained by matching the solutions at the interfaces between the barrier and matrix: (i) \(({e}^{i{k}_{{\rm{m}}}x}+R{e}^{-i{k}_{{\rm{m}}}x}){e}^{i{\rm{\Omega }}t}\) with \(({C}_{1}{e}^{i{k}_{{\rm{b}}}x}+{C}_{2}{e}^{-i{k}_{{\rm{b}}}x}){e}^{i{\rm{\Omega }}t}\) at x = 0 and (ii) \(({C}_{1}{e}^{i{k}_{{\rm{b}}}x}+{C}_{2}{e}^{-i{k}_{{\rm{b}}}x}){e}^{i{\rm{\Omega }}t}\) with \(T{e}^{i({k}_{{\rm{m}}}x+{\rm{\Omega }}t)}\) at x = L. To match the solutions we have to apply appropriate boundary conditions. The general formulation of the boundary conditions for exchange SWs should take into account possible change of exchange coupling at interfaces between the barrier and matrix. This coupling affects the phase shift acquired by SW when it passes through the interface, and thus modifies the group delay τgr. In our calculations we used Barnas-Mills boundary conditions (BMBC)41,42, which include the modification of exchange interaction at the interfaces both in the weak and strong coupling regime (see the Supplemantary Information for details). Using BMBC one finds the transmissivity T(Ω, L) in the form:

$$T({\rm{\Omega }},L)=\frac{{e}^{-i{k}_{{\rm{m}}}L}}{{{\rm{\Delta }}}_{c}\,\cos ({k}_{{\rm{b}}}L)+i{{\rm{\Delta }}}_{s}\,\sin ({k}_{{\rm{b}}}L)},$$

where Δs(km, kb) and Δc(km, kb) are the rational expressions of the form depending on the boundary conditions on the interface between matrix and barrier (see Supplementary Information for details).

The transmissivity T(Ω, L) is one of the most important spectral characteristics of the system. Its magnitude |T(Ω, L)| gives the information about the energy density, which is transmitted through/over the barrier. For Eq. (11), we can write the following expression for |T(Ω, L)|:

$$|T({\rm{\Omega }},L)|=|{{\rm{\Delta }}}_{{\rm{c}}}\,\cos ({k}_{{\rm{b}}}L)+i{{\rm{\Delta }}}_{{\rm{s}}}\,\sin ({k}_{{\rm{b}}}L{)|}^{-1}.$$

It is worth to notice that the transmissivity T(Ω, L) depends on the barrier width L only through the factors: sin(kbL), cos(kbL) and exp(kmL), presented explicitly in Eq. (11).

The group delay τgr depends on the phase of the transmissivity function. Following ref.24, we find τgr(Ω, L) in the form:

$${\tau }_{{\rm{g}}{\rm{r}}}({\rm{\Omega }},L)=\frac{1}{\gamma {\mu }_{0}{H}_{0}}\frac{d}{d{\rm{\Omega }}}[{\rm{Arg}}(T)+{k}_{{\rm{m}}}L\mathrm{].}$$

In the following, we will use the dimensionless group delay \({\tilde{\tau }}_{{\rm{g}}{\rm{r}}}\)(Ω, L), defined as:

$${\tilde{\tau }}_{{\rm{g}}{\rm{r}}}({\rm{\Omega }},L)=\gamma {\mu }_{0}{H}_{0}{\tau }_{{\rm{g}}{\rm{r}}}.$$

The phase ϕ = Arg(T) + kmL, gained by SW after tunnelling (propagating) through (over) the barrier, consists of two terms. The term kmL is a geometrical phase, which would be acquired by the SW on the distance L (width of the barrier) in the absence of the barrier, i.e. propagating in a homogeneous medium described by the material parameters of the matrix. The other term describes the phase shift resulting from the presence of the barrier. By referring to Eq. (11) we can notice that the phase ϕ can only be expressed by the argument of the denominator, Δccos(kbL) + iΔssin(kbL). This allows writing Eq. (13) in a more explicit form:

$${\tilde{\tau }}_{{\rm{g}}{\rm{r}}}({\rm{\Omega }},L)=-\,\frac{d}{d{\rm{\Omega }}}[{\rm{Arg}}({{\rm{\Delta }}}_{{\rm{c}}}\,\cos ({k}_{{\rm{b}}}L)+i{{\rm{\Delta }}}_{{\rm{s}}}\,\sin ({k}_{{\rm{b}}}L\mathrm{))].}$$

Hartman effect

For tunnelling SWs, the wave number kb is purely imaginary:

$${k}_{{\rm{b}}}=i{\kappa }_{{\rm{b}}},$$

where κb is real. Therefore, for a wide barrier (\(L\gg 1/{\kappa }_{{\rm{b}}}\)), one can make the following simplifications in Eq. (15): \(\cos ({k}_{{\rm{b}}}L)=\,\cosh ({\kappa }_{{\rm{b}}}L)\approx \tfrac{1}{2}{e}^{{\kappa }_{{\rm{b}}}L}\), \(\sin ({k}_{{\rm{b}}}L)=i\,\sinh ({\kappa }_{{\rm{b}}}L)\approx \tfrac{1}{2}i{e}^{{\kappa }_{{\rm{b}}}L}\). This brings us to the conclusion that the group delay \({\tilde{\tau }}_{{\rm{g}}{\rm{r}}}\) will saturate with increasing barrier width (L → ∞), which is the essence of the Hartman effect. In this limit, the group delay becomes independent on the barrier width:

$${\tilde{\tau }}_{{\rm{g}}{\rm{r}}}({\rm{\Omega }})\mathop{=}\limits_{L\to \infty }-\,\frac{d}{d{\rm{\Omega }}}[{\rm{Arg}}({{\rm{\Delta }}}_{{\rm{c}}}-{{\rm{\Delta }}}_{{\rm{s}}}\mathrm{)].}$$

It can be proved that the group delay in the tunnelling regime is always positive. Thus, the controversies related to the Hartman effect (including the discussion about the violation of causality) have nothing to do with negative group delay. In the limit L → ∞ the group delay diverges at the ranges of tunnelling regime, for Ω = 1 + \({\tilde{H}}_{{\rm{a}},{\rm{m}}}\) and Ω = 1 + \({\tilde{H}}_{{\rm{a}},{\rm{b}}}\).

One of the main obstacles making the observation of the HE difficult is the low magnitude of the transmissivity |T(Ω, L)| in the tunnelling regime, which decays exponentially with increasing barrier width L for \(L\gg 1/{k}_{{\rm{b}}}\), where one finds:

$$|T({\rm{\Omega }},L)|\mathop{=}\limits_{L\gg 1/{\kappa }_{{\rm{b}}}}{e}^{-{\kappa }_{{\rm{b}}}L}|{{\rm{\Delta }}}_{{\rm{c}}}-{{\rm{\Delta }}}_{{\rm{s}}}{)|}^{-1}\mathrm{.}$$

Therefore, it is useful to define the so-called figure-of-merit (FOM) for the HE:

$${\rm{FOM}}=\frac{|T|}{{\tilde{\tau }}_{{\rm{g}}{\rm{r}}}}.$$

The high value of the FOM points out the parameters of the model for which the short group delay coincides with the relatively high magnitude of the transmissivity.

The HE can be also observed for reflected waves, where the group delay is defined as24:

$${\tau ^{\prime} }_{{\rm{g}}{\rm{r}}}({\rm{\Omega }},L)=\frac{1}{\gamma {\mu }_{0}{H}_{0}}\frac{d}{d{\rm{\Omega }}}[{\rm{Arg}}(R\mathrm{)].}$$

The complex coefficient R is the reflectivity (see the discussion the beginning of this section). For a symmetric barrier, the group delays for transmitted waves τgr and for reflected waves τgr are equal43,44. This also means that for the barrier characterized by a symmetric shape of the effective anisotropy field: Ha(L/2 + x) = Ha(L/2 − x) and identical boundary conditions at x = 0, L, the saturated values of the group delay for transmitted and reflected waves will be also equal.

Numerical Results

Now we present numerical results obtained for the system under consideration. In Fig. 2 we show the absolute value of the transmissivity |T| (a, b) and the phase ϕ = Arg(T) + kmL gained by SW transmitted through (or over) the magnetic barrier (b, d) – both as a function of the frequency Ω and two selected model parameters (one of interface and another one of bulk character). More specifically, we show there the impact of interface exchange coupling (defined as \({\tilde{A}}_{{\rm{mb}}}={\lambda }_{\mathrm{ex},\mathrm{mb}}^{2}{M}_{S,\mathrm{mb}}^{2}/{H}_{0}^{2}\) – see Fig. 1 and Supplementary Information) (a, c), and the influence of a contrast between the bulk saturation magnetization of the barrier, MS,b, and of the matrix, MS,m (c,d). The results have been obtained with the use of general BMBC. These conditions, however, comprise other types of the boundary conditions considered here (see Supplementary Information).

Figure 2
figure 2

The absolute value of the transmissivity |T| (a,b) and the phase ϕ gained in the transmission (c,d) for the anisotropy barrier of height \({\tilde{H}}_{{\rm{a}},{\rm{b}}}\) + 1 = 5 and width L = 5, separated from the matrix by an interface layer of width t = 0.25 (widths are given in the units of λex). Both |T| and ϕ are presented as a function of the spin wave frequency Ω and material parameters: the strength of the interface exchange coupling, \({\tilde{A}}_{{\rm{m}}{\rm{b}}}={\lambda }_{{\rm{ex}},{\rm{mb}}}^{2}{\tilde{M}}_{S,{\rm{mb}}}^{2}\) (a,c) and the magnetization contrast between the barrier and matrix, \({\tilde{M}}_{{\rm{S}},{\rm{b}}}\)/\({\tilde{M}}_{{\rm{S}},{\rm{m}}}\) (b,d). Black dashed lines in (a,b) mark the maxima (|T| = 1) of the transmissivity. The frequencies Ωm = \({\tilde{H}}_{{\rm{a}},{\rm{m}}}\) + 1 = 1 and Ωb = \({\tilde{H}}_{{\rm{a}},{\rm{b}}}\) + 1 = 5 denote the minimum frequency for the propagating exchange SWs in homogeneous materials of the matrix and barrier, respectively. The later one is marked additionally by vertical white dashed line. The calculations have been done for the same values of exchange length λex = 1 in the barrier and in the matrix. The width of the barrier and the exchange length are measured in the same a.u. of length.

Transmission in the tunnelling regime (under barrier), i.e. for frequencies Ω < Ωb = \({\tilde{H}}_{{\rm{a}},{\rm{b}}}\) + 1), is very small, but it increases rapidly for Ω approaching Ωbb = 5 in Fig. 2). This increase is less rapid for stronger exchange coupling between the barrier and matrix (see Fig. 2a), and for the saturation magnetization in the barrier larger than that in the matrix region (see Fig. 2b).

For SWs propagating at frequencies Ω > Ωb (over barrier transmission), the transmissivity T oscillates with increasing Ω, see the maxima (resonances) indicated by the dashed lines in Fig. 2(a,b), for which |T(Ω)| = 1. For Ω > Ωb, the modulus of transmissivity, |T|, reveals sharp peaks in the regime of weak exchange coupling between the matrix and barrier (region of small interface exchange parameter in Fig. 2a). The weakest oscillations of |T| are observed for moderate values of the interface coupling (\({\tilde{A}}_{{\rm{mb}}}\) = 1 in Fig. 2a), corresponding to the natural boundary conditions (NBC) – see Supplementary Information. The oscillation amplitude of |T| increases again with increasing interface exchange parameter, which leads to deeper minima between the resonances. This behaviour can be even more clearly seen in Fig. 3(a,b), where |T| is shown as a function of Ω for two selected values of the interface exchange parameter, corresponding to the natural boundary conditions (Fig. 3a) and a weak interface coupling (Fig. 3b).

Figure 3
figure 3

The absolute value of the transmissivity |T| (a,b), the phase ϕ gained in the transmission (c,d), and the corresponding group delay (e,f) shown as a function of the spin wave frequency Ω. These parameters are shown for the anisotropy barrier of the same parameters as in Fig. 2, and for two different strengths of the exchange coupling \({\tilde{A}}_{{\rm{mb}}}\) between the barrier and matrix. The first column (a,c,e) presents the results for an intermediate strength of the coupling (which can be reduced to the case where the natural boundary conditions are applicable – see Supplementary Information), while the second column (b,d,f) shows the results in the regime of week coupling (for which the Hoffmann boundary conditions can be used – see Supplementary Information). Different colours correspond to: tunnelling through the barrier (red), propagation over the barrier (green), propagation in the homogeneous material: matrix (blue) or barrier (black). The calculations have been done for the same values of \({\tilde{M}}_{{\rm{S}}}\) = 1 and λex = 1 in the barrier and in the matrix.

The above -described properties of the transmissivity are similar to those observed for tunnelling of other waves existing in nature, including tunnelling of particles in quantum mechanics24. The exact correspondence to quantum mechanical tunnelling can be strictly shown for the NBC, when we neglect the contrast of MS between the matrix and barrier (see Fig. 3a).

The phase acquired in the transmission through (over) the barrier, ϕ = Arg(T) + kmL, is an important parameter describing the dynamical properties of wave propagation. Due to the fast changes of ϕ in the frequency domain, we observe large values of the group delay τgr (see Eqs 13 and 11). From Fig. 2(c,d) one can also notice that the phase ϕ grows (circulates) monotonously with the frequency Ω. Therefore, the group delay is positive as one might expect. The changes of ϕ (and also of τgr) vary, however, in the frequency domain. In a homogeneous system corresponding, e.g., to the matrix, the phase ϕm gained on the distance L is proportional to the wave number km, ϕm = Lkm. Due to a quadratic dispersion relation of the exchange SWs, the phase ϕm changes in the frequency domain as \(\sqrt{{\rm{\Omega }}}\), shifted by a constant value resulting from the static effective field. The magnetic barrier introduces an additional term, Arg(T), to the phase ϕ. This term reflects two features of the barrier, which influence the phase of SWs: (i) the difference in effective anisotropy fields and the contrast of material parameters (saturation magnetization and exchange length), which affect the wave number (see Eqs 9 and 10); (ii) the strength of exchange coupling at the interface between the barrier and matrix included in the boundary conditions (see Supplementary Information), which determines the jump of the phase at these interfaces. For moderate coupling of the barrier and matrix, the correction Arg(T) makes the ϕ(Ω) relation similar to that in the homogeneous system made of the material used to create the barrier, ϕ ≈ kbL (see Fig. 3c), with some hardly noticeable deviation close to Ωb and at the frequencies corresponding to the transmission resonances, where |T(Ω)| = 1 (see the inset in Fig. 3c). These oscillations in the slope of ϕ(Ω) are responsible for the peaks in the group delay τgr, clearly seen in Fig. 3e. Note that for the homogeneous systems τgr(Ω) decays monotonously with increasing Ω (see the solid blue and dashed black lines in Fig. 3e). The oscillations in Arg(T) are related to the transmissivity resonances, |T| = 1. The phase increases approximately by π between two successive resonances (this rule is strict for weak interface exchange coupling). Due to a quadratic dispersion relation (\({\rm{\Omega }}\propto {k}_{\alpha }^{2}={({\phi }_{\alpha }/L)}^{2}\)), the distance between successive resonances and peaks of the group delay increases.

The impact of interface exchange coupling and contrast of magnetization (between the barrier and matrix) on the group delay can be deduced from Fig. 2(c,d). The following conclusions can be drawn for the propagation regime (Ω > Ωb): For weaker interface exchange coupling \({\tilde{A}}_{{\rm{mb}}}\) and \({\tilde{M}}_{{\rm{S}}}\) in the barrier lower than \({\tilde{M}}_{{\rm{S}}}\) in the matrix one finds, (i) the phase ϕ changes more rapidly in the frequency domain and therefore the peaks in τgr are expected to be higher, and (ii) there are more phase oscillations and more peaks in τgr per frequency unit. These changes can be attributed to the reduction of spin wave pinning for the weaker interface exchange coupling \({\tilde{A}}_{{\rm{mb}}}\) and extension of the wavelength in the barrier for lower \({\tilde{M}}_{{\rm{S}}}\) inside the barrier.

From Fig. 2(c,d) one can conclude that in the tunnelling regime, Ωm < Ω < Ωb, the phase changes more rapidly just above the lowest allowed frequency of propagating SWs in the matrix, Ωm = \({\tilde{H}}_{{\rm{a}},{\rm{m}}}\) + 1, and just below the frequency Ωb (determining the threshold between tunnelling and propagation regime). At these frequencies, the slope of the ϕ(Ω) dependence is infinite for homogeneous materials of both the matrix and the barrier. This results in infinite values of the group delay τgr for homogeneous materials (at the mentioned frequencies), which is supposed to influence the value of τgr for the system composed of the barrier embedded in the matrix. It is also worth to notice that the phase shift ϕ (between the transmitted and incoming wave) is surprisingly negative for the very low frequencies (close to the Ωm) and then, it increases for larger frequencies and reaches positive values close to Ωb.

Figure 3 shows the modulus of the transmissivity |T(Ω)| (a,b), the phase ϕ(Ω) gained by SW after transmission (c,d), and the corresponding group delay τgr(Ω) (e,f). The numerical results on ϕ(Ω) and τgr(Ω) for the barrier embedded in the matrix are supplemented by the phase of SWs propagating in the homogeneous material of the barrier and matrix, acquired at the distance equal to the width of the barrier, as well as with the plots of the corresponding group delays. These plots have been obtained for the structure without contrast of bulk magnetic parameters (\({\tilde{M}}_{{\rm{S}}}\) and λex). Using the BMBC we analyzed two special cases: intermediate exchange coupling at the interface, corresponding to the NBC, and weak interface coupling, where the Hoffman boundary conditions (HBC) are applicable45 – see Supplementary Information. The plots in Fig. 3(a,c) are strictly counterparts of the corresponding plots for electronic waves, reported e.g in ref.24. The plots presented in Fig. 3 give more detailed insight into the transmission properties of SWs tunnelling (propagating) through (over) the magnetic barrier. The interesting effect is observed in Fig. 3(b). For a small value of Amb, we can see the resonate transmission of spin waves. It means that in such conditions the barrier region is almost decoupled from the matrix and the transmission peaks are supposed to be sharp even for the spin waves of high frequency propagating over the barrier. For lower frequencies, we observed that the group delay of tunnelling spin waves \({\tilde{\tau }}_{{\rm{gr}}}\) (red line in Fig. 3(e,f)) is shorter than in uniform space \({\tilde{\tau }}_{\text{gr},m}\) (blue line in Fig. 3(e,f)) by the cost of reduction of transitivity |T| (compare the red lines in Fig. 3(a,b)). This difference increases for weaker coupling Amb (compare the red lines in Fig. 3(e,f)).

To discuss the HE one needs to analyze in detail the properties of the considered system in the tunnelling regime. In Fig. 4 we show the absolute value of the transmissivity modulus |T| (a,d), the group delay \({\tilde{\tau }}_{{\rm{gr}}}\) (b,e), and the corresponding FOM (c,f) – all as a function of frequency Ω and material parameters: interface exchange coupling (a-c) and contrast of saturation magnetization between the barrier and matrix (d–f). All the quantities, that is |T|, \({\tilde{\tau }}_{{\rm{gr}}}\) and FOM, are shown in the logarithmic scale. The yellow regions in this figure correspond to large values of the corresponding parameter.

Figure 4
figure 4

The logarithm of the transmissivity modulus (a,d), group delay (b,e), and FOM (c,f) in the tunnelling regime, Ωm < Ω < Ωb. All parameters are presented as a function of spin wave frequency Ω and material parameters: the strength of the interface exchange coupling \({\tilde{A}}_{{\rm{mb}}}\) (ac) and the magnetization contrast between the barrier and matrix, \({\tilde{M}}_{{\rm{S}},{\rm{b}}}\)/\({\tilde{M}}_{{\rm{S}},{\rm{m}}}\) (df). The calculations have been done for the same values of the exchange length λex = 1 in the barrier and in the matrix. The parameters of the barrier are the same as the ones used in Fig. 2.

The observation of HE requires optimally large amplitude of the tunnelling SWs. This means that one should consider spin wave packets in the frequency range not very distant from the threshold frequency Ωb corresponding to the top of the magnetic barrier. The other requirement is a relatively small value of the group delay, which can allow the detection of SWs after passing the magnetic barrier of a certain width in the presence of damping. The last column in Fig. 4 (see (c,f)) shows the FOM defined as the ratio of tunnelling amplitude and group delay. The yellow regions indicate the range of parameters which are the most suitable for experimental observation of the HE.

The modulus of the transmissivity |T| decays exponentially with decreasing frequency. Therefore, for practical application, only the higher range of frequencies, close to Ωb, is of some interest. The increase of the interface exchange coupling or saturation magnetization in the barrier can slightly extend this range towards lower frequencies. The group delay, \({\tilde{\tau }}_{{\rm{gr}}}\), reaches the lowest values for intermediate frequencies, between the lowest frequencies for propagating modes in the matrix (here Ωm = 1) and in the barrier (here Ωb = 5). The further lowering of \({\tilde{\tau }}_{{\rm{gr}}}\) could be achieved by reducing the interface exchange coupling or saturation magnetization in the barrier (with respect to that in the matrix) – see Fig. 4(b,e). Unfortunately, this change simultaneously leads to a decrease of |T|. The better strategy is thus to increase the saturation magnetization contrast by taking larger values of \({\tilde{M}}_{{\rm{S}}}\) in the barrier (see Fig. 4e). However, the changes of \({\tilde{\tau }}_{{\rm{gr}}}\) with frequency Ω are not so large as the changes in the transmissivity modulus |T|. Therefore, the decisive factor for increasing the FOM, which makes the observation of the HE possible, is the optimization of the modulus of the transmissivity by selection of the frequency range slightly below the threshold value Ωb, and selection of appropriate values of material parameters (e.g. by the increase of \({\tilde{M}}_{{\rm{S}}}\) in the barrier region with respect to that in the matrix).

Now we present the results which demonstrate the HE for the exchange-dominated SWs. Figure 5 shows the saturation of the group delay with increasing barrier width in the tunnelling regime (red curves), which can be considered as a manifestation of the HE. The presented results (Fig. 5) have been obtained for the BMBC, which in the regime of intermediate interface exchange coupling (a,c) and weak exchange coupling (b,d) reduce to the NBC and the HBC, respectively. Let us analyze these results in more details. First, we note that the group delay for the under-barrier tunnelling behaves in a different way than that for the over-barrier propagation. In the former case, the group delay at small thicknesses L is larger than the time which SW needs to traverse the distance L in the free space (no barrier). In the free space, i.e. in the homogeneous medium made of the matrix material, the group delay increases linearly with the distance, \({\tilde{\tau }}_{{\rm{g}}{\rm{r}},\alpha }=L\frac{d{k}_{\alpha }}{d{\rm{\Omega }}}=L{v}_{{\rm{g}}{\rm{r}},\alpha }\), where vgr,α is the group velocity in the homogeneous material. For larger values of L, the group delay increases more slowly than in the case of free motion. Moreover, the group delay saturates with increasing L (see the red lines in Fig. 5(a,b)). In turn, the group delay for the over-barrier propagation reveals oscillations with increasing L, but overall it increases linearly with increasing L (see the green curves in Fig. 5a plotted for the NBC, which correspond to an intermediate strength of the interface exchange coupling). The oscillations in the group delay can be significantly stronger in the regime of weak interface exchange coupling, see the green curves in Fig. 5b, where the HBC can be applied. The observed peaks in \({\tilde{\tau }}_{{\rm{g}}{\rm{r}}}\) (and also those in |T|) are related to the resonant tunnelling, which can be achieved by the selection of frequency/wavelength or by adjusting the width of the barrier. It is worth to note that even in the regime of weak interface coupling (see the green curves in Fig. 3(b,f)) the linear growth with L is observed both for the maxima of \({\tilde{\tau }}_{{\rm{g}}{\rm{r}}}\) peaks and for the minima between them.

Figure 5
figure 5

Dependence of the group delay τgr on the barrier width L for the selected frequencies Ω and for two different strengths of interface exchange coupling \({\tilde{A}}_{{\rm{mb}}}\) between the barrier and matrix. The first column (a,c) presents the results for intermediate strength of the coupling (which can be reduced to the case where the natural boundary conditions are applicable). The second column (b,d) shows the results in the regime of week coupling (for which the Hoffmann boundary conditions can be used). The saturation of the group delay, being the signature of HE, appears in the tunnelling regime (Ωm < Ω < Ωb) and is shown in more details in (c,d). The calculations were performed for the same values of \({\tilde{M}}_{{\rm{S}}}\) = 1 and Aex = 1 in the barrier and matrix. The parameters of the barrier are the same as the ones used in Fig. 2.

In the tunnelling regime (under-barrier transmission), the group delay \({\tilde{\tau }}_{{\rm{g}}{\rm{r}}}\)(L) saturates with increasing L (see Fig. 5(c,d)). The saturation with increasing L is slower for the higher frequencies which are closer to the threshold value Ωb. This property makes the observation of the HE difficult because it requires to use wide barriers. Note, that this frequency range is characterized by high values of the FOM, which is beneficial for spin wave transmission. It is also worth to note that for higher, or even intermediate strengths of the interface exchange coupling, the dependence of the group delay on the barrier width is non-monotonous for the lowest frequencies (see the curves for Ω = 1.25, 1.5 in Fig. 5c.

There is one interesting feature of the group delay curves shown in Fig. 5(c,d). Namely, in Fig. 5(c) the group delay vanishes in the limit L → 0, while in Fig. 5(d) a small nonzero value of the group delay remains when L = 0. This follows from the fact that although L is reduced to zero, the modified exchange coupling at the barrier/matrix boundaries (\({\tilde{A}}_{{\rm{mb}}}\) = 0.13) remain in Fig. 5(d) when L is reduced to zero. To achieve a uniform system in the limit of L = 0 one should also restore the full coupling limit.

It is clear from Fig. 5(c,d) that the saturation level of the group delay changes with the frequency, displaying a minimum in the tunnelling range Ωm < Ω < Ωb. This is shown explicitly in Fig. 6. From Fig. 6(a) follows that for the barrier thickness L = 5 (assumed earlier for calculations presented in Figs 2, 3 and 4), the group delay is almost saturated. Figure 6(a) was obtained for the NBC in the absence of saturation magnetization contrast (like Fig. 3(a,c,e) and Fig. 5(b,c)). We can trace here in detail the effect of reducing the slope of \({\tilde{\tau }}_{{\rm{g}}{\rm{r}}}\)(L) with increasing Ω and the non-monotonic character of the \({\tilde{\tau }}_{{\rm{g}}{\rm{r}}}\)(L) relation for the lowest frequencies (shown in the inset).

Figure 6
figure 6

(a) Group delay as a function of the barrier thickness and frequency for the natural boundary conditions (see Supplementary Information) applied at the interface between the barrier and matrix. The peculiarities related to the non-monotonous dependence of τgr(L) are zoomed in the inset. (b) Frequency dependence of the saturation value of the group delay, τgr(L → ∞), for the indicated values of the exchange coupling between the barrier and matrix \({\tilde{A}}_{{\rm{mb}}}\). The calculations have been done for the same values of \({\tilde{M}}_{{\rm{S}}}\) = 1 and λex = 1 in the barrier and matrix. The inset in (b) presents the dependence of minimal τgr(L → ∞) on \({\tilde{A}}_{{\rm{mb}}}\). The parameters of the barrier are the same as those used in Fig. 2.

The changes of the saturation level \({\tilde{\tau }}_{\text{gr},\infty }\) with the frequency Ω are shown even more clearly in Fig. 6(b) for few selected values of the exchange coupling between matrix and barrier: Amb. The minimum of this dependence becomes deeper with decreasing Amb (see inset in Fig. 6(b)), and is shifted towards higher frequencies. The shorter group delay is beneficial for observation of the HE. The better strategy to increase the FOM for the HE is to select the central frequency of tunnelling wave package close to the minimum of the dependence: \({\tilde{\tau }}_{\text{gr},\infty }\)(Ω) than to reduce the coupling: Amb. Because the latter approach will result in significant the decrease of the |T|.

By reducing \({\tilde{\tau }}_{\text{gr},\infty }\) we can potentially gain, for narrower barriers, the condition: \({\tilde{\tau }}_{{\rm{gr}}}\) < \({\tilde{\tau }}_{{\rm{gr}},{\rm{m}}}\) (delay time for tunnelling is shorter than the delay in uniform space). This condition is more useful for the experimental search for the signatures of the HE than looking for the saturation of group delay with the increase of the barrier width.

To check how the model described above refers to real systems (see Fig. 1), we performed numerical calculations for a thin layer of CoFeB, which is slightly thinner in the barrier region (tCoFeB,b = 1.0 nm) than in the matrix area (tCoFeB,m = 1.3 nm). The saturation magnetization in thin ferromagnetic layers is usually reduced. For the CoFeB layer of the considered thickness, we assumed the following values of MS: MS,m = 1.2 × 106 A/m and MS,b = 0.8 × 106 A/m46. We also took into account a slight reduction of the exchange stiffness constant in the barrier in reference to its value in the matrix: Am = 27 × 1012 J/m in the matrix region and Ab = 20 × 1012 J/m in the barrier46. To induce the out-of-plane anisotropy, the CoFeB layer is covered by MgO overlayer. For the strong anisotropy of the CoFeB/MgO interface: Ki = 1.3 × 10−3 J/m238, both the matrix and barrier are perpendicularly magnetized, with strong effective anisotropy fields: μ0Ha,m = 0.16 T and μ0Ha,m = 2.24 T, respectively. We also assumed an external magnetic field μ0H0 = 0.5 T applied perpendicularly to the magnetic layer. The corresponding transmissivity and group delay are shown in Fig. 7 for the barrier width L = 30 nm. Apart from this, we assumed tmb = 2 nm for the width of the interface between the matrix and the barrier. At this interface we assumed MS,mb and λex,mb corresponding to NBC (see Supplementary Information). In the numerical calculation we used the BMBC with the additional term related to surface anisotropy, which was omitted in analytical considerations and which was irrelevant for the results presented in Figs 26.

Figure 7
figure 7

Modulus of the transmissivity |T| (a) and the corresponding group delay τgr (c) for the CoFeB layer of thickness tCoFeB,m = 1.3 nm and tCoFeB,b = 1.0 nm in the matrix and the barrier region, respectively. For |T| and τgr we assumed the width of the barrier L = 30 nm. The thickness of the interface between the matrix and the barrier was assumed as ttm = 4 nm. The following material parameters were assumed: MS,m = 1.2 × 106 A/m, MS,b = 0.8 × 106 A/m, Am = 27 × 1012 J/m, Ab = 20 × 1012 J/m, Ki = 1.3 × 10−3 J/m3. The calculations were performed for external field μ0H0 = 0.5 T. Saturation of the group delay τgr, observed in the tunnelling regime is shown in (b). The change of the saturation value of τgr,∞ as a function of frequency (d) shows the minimum around 55 GHz.

In Fig. 7 we present the transmission characteristics for the high frequency of SWs passing through the anisotropy barrier formed in the CoFeB layer, as described above. Both the transmissivity (Fig. 7(a)) and group delay (7(c)) have typical forms and are similar to those presented in Fig. 3. We were able to adjust the parameters of the model to observe the saturation of the group delay for a relatively narrow barrier, L = 30 nm. For this width of the barrier we observe noticeable values of |T| in the tunnelling regime for γμ0ω < Ha,b + H0 (red part of the plot in Fig. 7(a)). As a result, the FOM which determines the observation possibility of the HE is slightly enhanced. For instance, for the frequency f = 65 GHz we obtain FOM = 0.16 (cf. Figure 4(c,f)). The relatively small number of the oscillations (resonances) of |T| for γμ0ω > Ha,b + H0 (green part of the plot in Fig. 7(a)) results from a relatively narrow width of the barrier assumed here. The larger amplitude of these oscillations originates from the significant contrast of MS in the matrix and barrier.

Figure 7(b,d) illustrate the occurrence of the HE in the considered system. One can note the saturation of the group delay τgr for larger widths L of the barrier. The saturation is slower (faster) for higher (lower) frequencies, similarly as in Fig. 5(c,d). By a careful inspection of Fig. 7, one finds that the group delay does not approach zero for L → 0 (see the red dashed lines). This behaviour can be understood when we take into account the fact that the influence of the interface anisotropy field, present in the BMBC, survives in the limit of L → 0, and gives rise to the nonzero values of τgr in this limit. To get a uniform system in the limit of L → 0, and thus also a vanishing group delay, one should simultaneously adjust the interface anisotropy to that in the matrix.

In the numerical studies the saturation value of τgr,∞ was approximated by the group delay τgr calculated for an extremely wide barrier: L = 200 nm (plotted in Fig. 7(d)). The further extension of the barrier practically does not change τgr. The dependence of τgr,∞ on the frequency, presented in Fig. 7(d), is qualitatively similar to that in Fig. 6(b).


In this paper, we have analyzed the Hartman effect for high-frequency (few tens of GHz) spin waves tunnelling through a narrow (few tens of nm) magnetic barrier. We investigated a planar system where the barrier was formed by the local increase of a perpendicular magnetic anisotropy. Such an increase may appear due to the specific fabrication of the system – we propose to change the thickness of CoFeB layer covered by MgO to modify spatially the effective out-of-plane anisotropy field. The interesting extension of our studies would be the investigations of the system where the anisotropy in the barrier can be tuned on demand. This can be achieved owing to the magnetostriction effect where, with the aid of piezoelectric transducers, the height of the anisotropy barrier can be adjusted in a certain range by the application an external electric field47.

By calculating the spin wave transmissivity, we have determined the group delay and found its saturation with increasing barrier width. This proves the existence of the Hartman effect for spin waves. We discussed the impact of exchange boundary conditions (determined by the exchange coupling between the barrier and surrounding material Amb) on the group delay and Hartman effect. We found that decrease of Amb results in the shortening of group delay for tunnelling spin waves by the cost of the reduction of the transitivity.

One should mention that for an exchange dominated system the shape of the transmitted and reflected wave packets is remarkably modified, which follows from the frequency dependence of the transmissivity. This problem can be solved when we consider the tunnelling of dipolar spin waves which can be characterized by linear dispersion relation in range of small wave vectors. However, in the dipolar regime we are limited to lower operating frequencies and restricted to larger sizes of the devices (due to the increase in their wavelengths).