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Excitation of coupled spin–orbit dynamics in cobalt oxide by femtosecond laser pulses

Nature Communicationsvolume 8, Article number: 638 (2017) | Download Citation


Ultrafast control of magnets using femtosecond light pulses attracts interest regarding applications and fundamental physics of magnetism. Antiferromagnets are promising materials with magnon frequencies extending into the terahertz range. Visible or near-infrared light interacts mainly with the electronic orbital angular momentum. In many magnets, however, in particular with iron-group ions, the orbital momentum is almost quenched by the crystal field. Thus, the interaction of magnons with light is hampered, because it is only mediated by weak unquenching of the orbital momentum by spin–orbit interactions. Here we report all-optical excitation of magnons with frequencies up to 9 THz in antiferromagnetic CoO with an unquenched orbital momentum. In CoO, magnon modes are coupled oscillations of spin and orbital momenta with comparable amplitudes. We demonstrate excitations of magnon modes by directly coupling light with electronic orbital angular momentum, providing possibilities to develop magneto-optical devices operating at several terahertz with high output-to-input ratio.


The inverse effect of the magneto-optical Faraday effect, specifically light acting on magnetic systems, was first attempted by Faraday in 18451 and verified more than 100 years later2, 3. Nowadays, the various inverse magneto-optical effects (the inverse Faraday effect (IFE) or the inverse Cotton–Mouton effect (ICME))4 are used for non-thermal optical excitation of spin oscillations with frequencies in the terahertz range in transparent antiferromagnets5,6,7. The effects enable the control of spin dynamics using optical polarization. In contrast to a recent realization of a non-trivial spin evolution for opaque metallic ferrimagnets8, 9, non-thermal excitation does not lead to intense heating of the sample. This feature attracts particular attention for possible applications of antiferromagnets in magnetic recording and magneto-optical devices, e.g., terahertz radiation sources10, 11 and optomagnonic read–write transfer12.

The coupled spin–orbit dynamics of cobalt oxide CoO has been studied for half a century. For CoO, quenching of the orbital angular momentum of a free Co2+ ion (L free = 3) by the cubic crystal field is only partial, resulting in an effective angular momentum of L = 1 (orbital triplet), which should be treated as an additional degree of freedom in the magnetic subsystem of CoO. Being subject to a low-symmetry crystal field, the ions with partial unquenching increase magnetic anisotropy (see ref. 13 and Supplementary Note 1); its magnitude is comparable to those of the effective spin–orbit and exchange interactions. All these specific features lead to magnon modes originating from spin and orbital degrees of freedom and the magnon frequencies are much higher than those for standard antiferromagnets containing transition-metal ions14. The magnon modes of CoO have been investigated using Raman scattering15, infrared absorption13, 16, infrared reflection17 and inelastic neutron scattering18, 19, but their interpretation and theoretical description are still being debated. Further, the coupling of femtosecond laser pulses and unquenched orbital angular momentum has never been explored.

In the following, we report highly efficient non-thermal coherent excitation of magnon modes in CoO using femtosecond laser pulses at frequencies up to 9 THz. Symmetry analysis and a theoretical model calculation confirm the excitation of these modes, which consist of coupled dynamics that have comparable amplitudes of the oscillations of spin and orbital angular momenta.


Analysis of magnon modes in CoO

Below the Néel temperature T N = 292 K, CoO exhibits an antiferromagnetic order with the antiparallel spin orientations of Co2+ ions belonging to two sublattices (labeled with 1 and 2), S 1 and S 2 (effective S = 3/2). The unquenched part of the orbital angular momenta (effective L = 1) of Co2+ ions, L 1 and L 2 are expected to be antiparallel to the corresponding spin momenta for any sublattice because of the spin–orbit interaction. For the crystallographic and magnetic structures (Fig. 1a), CoO exhibits a low-symmetry monoclinic ground state (crystal point group 2/m) with spin directions inclined from the crystalline axis [001] by an angle ρ. The value sin ρ = \(\sqrt {2{{\rm /}}51} \) is commonly accepted now20. We choose a coordinate system with the z-axis along this direction and \({\hat{\bf y}}||[\bar 110]\).

Fig. 1
Fig. 1

Experimental geometries and excited magnon modes. a Crystallographic and magnetic structures of CoO in the coordinate system. Cobalt atoms are shown as cyan spheres. Blue and green arrows represent spin and orbital angular momenta, respectively. Oxygen atoms are shown as yellow spheres. b Illustration of the four transverse magnon modes of CoO: Γ1(S), Γ2(S), Γ1(L) and Γ2(L). Spin (S 1, S 2) and orbital (L 1, L 2) angular momenta are represented as cyan and yellow arrows, respectively. m S  = S 1 + S 2, m L  = L 1 + L 2, \({{\bf{n}}_S} = {{\bf{S}}_1} - {{\bf{S}}_2} - {N_S}{\hat{\bf z}}\) and \({{\bf{n}}_L} = {{\bf{L}}_1} - {{\bf{L}}_2} - {N_L}{\hat{\bf z}}\) are shown as red, magenta, blue and green arrows, respectively. The ratio of the amplitude of the variables (m S ), (m L ), (n S ) and (n L ) are Γ1(L): (m L ) y /(m S ) y  = −1.02, (n L ) x /(n S ) x  = 1.17; (n S ) x /(m S ) y  = −0.62, Γ1(S): (m L ) y /(m S ) y  = −0.57,(n L ) x /(n S ) x  = −0.65; (n S ) x /(m S ) y  = −2.36, Γ2(L): (n L ) y /(n S ) y  = = 1.65; (m L ) x /(m S ) x  = −1.50, (n S ) x /(n S ) y  = −1.61, Γ2(S): (n L ) y /(n S ) y  = −0.44; (m L ) x /(m S ) x  = 0.40, (n S ) x /(n S ) y  = −0.25. c Transverse and (d) longitudinal geometries. θ and ϕ denote the azimuthal angles of the pump and probe polarizations from the reference axes, which are [001] and [100] in transverse and longitudinal geometries, respectively

In CoO, the coupled spin–orbit dynamics provides a complex combination of magnon modes with different symmetries and frequencies. We introduce convenient combinations of the variables, total spin angular momentum m S  = S 1 + S 2, total orbital angular momentum m L  = L 1 + L 2 (in the ground state m S  = m L  = 0), and spin and orbital antiferromagnetic vectors, N S  = S 1 − S 2 and N L  = L 1 − L 2, respectively. The antiferromagnetic vectors can be present through their values in the ground state \({N_{S,L}}{\hat{\bf z}}\) and the small deviations from the ground state, \({{\bf{n}}_{S,L}} \bot {\hat{\bf z}}\). Our theoretical analysis (see Supplementary Note 1 and 2) suggests that four transverse magnon modes should be observed, which are classified into two modes with different symmetries (Γ1 and Γ2). These magnon modes (Fig. 1b) belong to two symmetry classes: (1) Γ1(S) and Γ1(L)-modes with nonzero (n S ) x , (n L ) x , (m S ) y and (m L ) y ; and (2) Γ2(S) and Γ2(L) modes with nonzero (n S ) y , (n L ) y , (m S ) x and (m L ) x 14. Here, (S) and (L) denote spin- and orbital-dominated modes, respectively. They should exhibit different polarization dependence in the magneto-optical experiments.

Experimental geometries

To demonstrate the coherent excitation of magnons in CoO and to investigate these complex dynamics and symmetries of the magnons, we performed time-resolved pump–probe experiments. Here, optical pulses excite the magnons through the IFE and the ICME. In particular, we carefully chose the crystalline orientation and the optical polarizations to distinguish magnon modes with different symmetries. In the transverse and longitudinal geometries (TG and LG, respectively), the pump beam propagates along the [100] and [001] directions, which are nearly perpendicular and parallel to the z axis (Fig. 1c, d, respectively). The electric field of the pump light has the form \({{E_i}(t) = {{\rm Re}}\left[ {{{\cal E}_i}}(t){{\rm e}^{i\omega t}} \right]}\). The time-dependent complex amplitude of the electric field \({{\cal E}_i}(t)\) takes the form \({{\cal E}_{[001]}}(t) \equiv {{\cal E}_0}(t){{\rm cos}}\,\theta \), \({{\cal E}_{\left[ {0\bar 10} \right]}}(t) \equiv {{\cal E}_0}(t){{\rm sin}}\,\theta {{\rm e}^{i\psi }}\) in the TG, and \({{\cal E}_{[100]}}(t) \equiv {{\cal E}_0}(t){{\rm cos}}\,\theta \), \({{\cal E}_{[010]}}(t) \equiv {{\cal E}_0}(t){{\rm sin}}\,\theta {{\rm e}^{i\psi }}\) in the LG, where 0° ≤ θ < 180°, −90° ≤ ψ ≤ 90°. For linearly polarized light, ψ = 0 with angle θ determining the azimuth of the polarization; for circularly polarized light, θ = 45° and ψ = 90° determine the two different helicities σ±. For both geometries, pump pulses were circularly polarized (σ±) or linearly polarized with different values of θ. For experimental details, see Methods.

Magnon excitation in the TG

Figure 2a expresses the change Δf in probe polarization, see Methods for definition, as a function of delay time t in the TG. Figure 2b gives the Fourier-transformed amplitude spectra of the oscillations for θ = 94° in Fig. 2a. Excitations with frequencies of 4.4, 6.6 and 8.9 THz are clearly observed. These modes have been attributed to magnetic excitations15.

Fig. 2
Fig. 2

Terahertz magnon modes in the transverse geometry. a Change Δf in probe-light polarization as a function for the delay time from the pump light to the probe light at T = 5 K in the transverse geometry. Pump pulses were linearly polarized with different values of θ or circularly polarized σ± (ψ = 90°). b Fourier-transformed amplitude spectrum of the result with θ = 94° in (a). c, d Pump polarization dependence of the signed amplitude F in the 4.4, 6.6 and 8.9 THz modes fitted by function Δf(t) ≡ FeαΩt sin(Ωt + ϑ). The fitted results of F at 4.4 THz (solid line), 6.6 THz (dotted line) and 8.9 THz (dashed line) are shown as functions of θ for linear polarizations (c) and of ψ for circular polarizations (d). The error bars represent the SD of the measurements

The temporal evolutions of the probe polarization observed in the TG were fitted by a superposition of damped oscillations \(\Delta f(t) \equiv \mathop {\sum}\nolimits_{j = 1}^3 {{F_j}{{\rm e}^{ - {\alpha _j}{\Omega _j}t}}{{\rm sin}}\left( {{\Omega _j}t + {\vartheta _j}} \right)} \) with three frequencies Ω j /2π = 4.4, 6.6 and 8.9 THz, and damping constants α j  = 0.011 ± 0.001, 0.004 ± 0.002 and 0.009 ± 0.003 for j = 1, 2 and 3, respectively. Here, F j is defined as the signed amplitude that may take negative values. Figure 2c, d shows the signed amplitude F j for linear and circular polarizations of pump, respectively. From Fig. 2c, the dependence of the pump polarization is almost proportional to (1 − cos 2θ) for the 4.4-THz mode, cos 2θ for the 8.9-THz mode and (cos 2θ + const.) for the 6.6-THz mode, where const. is neither 0 nor −1. Surprisingly, for a circularly polarized pump beam, the amplitudes were almost independent of helicity σ± and nearly equal to that for a linearly polarized pump beam with θ = 45°, 135°.

To explain this complicated picture, let us consider the phenomenological theory (see Supplementary Note 3 for detail). The (inverse) magneto-optical effects result from the dependence of the permittivity on the magnetic order parameter21. Namely,

$$\delta {\varepsilon _{ij}} = i{k_{ijk}}{m_k} + 2{g_{ijkl}}{N_k}{n_l},$$

where k ijk and g ijkl determine the Faraday effect (FE) and the Cotton–Mouton effect (CME) (both direct and inverse), respectively. Here, k ijk  = −k jik , g ijkl  = g jikl  = g ijlk , the structures of these tensors are determined by the magnetic symmetry group of the crystal22, 23. It is noteworthy that the subscript “l” is not related to the orbital angular momentum, but a lower index for a tensor “ijkl”. For materials such as CoO with partially unquenched orbital angular momentum, the independent dynamics of the spin and orbital angular momenta should be considered. Formally, the independent contributions of these momenta, m S , n S or m L , n L can be written down in the form given in Eq. (1). The symmetric properties of the oscillations of the corresponding spin and orbital vectors are indeed the same, as well as the symmetric properties of the tensors k ijk and g ijkl . Although both the orbital and spin angular momenta contribute to the magnetism in CoO, the magneto-optical effect is dominated by the orbital angular momentum because the optical selection rule for the electric-dipole interaction only allows changes in orbital angular momentum. A change in spin can be only allowed via spin–orbit interactions. In many other systems, however, the orbital angular momentum is quenched and cannot contribute to the magnetic properties of media, and thus magneto-optical effect is governed by the indirect coupling between spin and light24. To simplify the expressions, we omit the index “L” from vectors m L , n L in the following. The effective energy of the magneto-optical interaction with the use of Eq. (1) for TG can be written as:

$$W_{{{\rm TG}}}^{{{\rm MO}}}(t) = - \frac{{I(t)}}{{16\pi }}[ {( {{G_1} + {G_2} + {G_3}} ){n_x} + ( {{G_1} - {G_2} - {G_3}} ) } \\ {n_x}{{\rm cos}} \, 2\theta - {G_4}{n_y}( {1 - {{\rm cos}}\,2\theta } ) \hskip 5pc \\ + ( {{G_5}{n_x} + {G_6}{n_y}} ){{\rm sin}}\,2\theta \,{{\rm cos}}\,\psi \hskip 5.3pc \\ + ( {{K_1}{m_y} - {K_2}{m_x}} ){{\rm sin}}\,2\theta \,{{\rm sin}}\,\psi ], \hskip 4.55pc$$

where \(I(t) = {\cal E}(t){{\cal E}^*}(t)\) for a given polarization of light. Here, Ks and Gs are related to the FE and CME (both direct and inverse), respectively, and are defined in Supplementary Eqs. (20)–(28).

When a material has high symmetry, such as cubic symmetry, the parameters G 1, G 2, G 3 and G 4 are zero and the amplitude of the magnetic oscillation induced by the ICME gives sin 2θ cos ψ dependence in Eq. (2)12, 25,26,27. This implies that its sign changes when the pump azimuthal angle θ is changed from 45° to 135° for linearly polarized light (i.e., ψ = 0°), and that it vanishes for circularly polarized light (ψ = ±90°). Until very recently, magnetic excitations with only this particular polarization dependence were considered to originate from the ICME. However, the magnon modes experimentally observed in the TG never exhibit standard sin 2θ cosψ dependence. In a crystal with a reduced symmetry like in CoO, other G-related terms, G 1G 4, can also appear in Eq. (2). These terms may lead to magnetic oscillations induced by the ICME that are independent of helicity (ψ) and proportional to cos 2θ or (1 − cos 2θ). It is noteworthy that the (1 − cos 2θ) contribution from ICME does not vanish even for circularly polarized light with cos 2θ = 0 and the amplitude for circular polarization should be equal to that for linear polarization with θ = 45° and 135°, as mentioned above. This relationship enables other mechanisms to be excluded, e.g., thermal excitation. This helicity-independent excitation of the magnon modes by circularly polarized light is a non-standard manifestation of the ICME and is a characteristic of materials with low symmetry28.

Magnon excitation in the LG

Figure 3a shows Δf as a function of t in the LG. The amplitude of oscillations in Δf reaches large values, as high as 0.02. The output-to-input ratio, which is defined as the amplitude of oscillation in Δf normalized by the pump fluence and pump–probe spectral weight is two orders of magnitudes higher than that observed in NiO28 (see Supplementary Note 4). It is noteworthy that Δf was measured under non-resonance conditions for both CoO and NiO. This demonstrates the high efficiency of the optical excitation for magnets with unquenched orbital angular momentum. Figure 3b presents the Fourier-transformed amplitude spectrum of the oscillations for θ = 0° in Fig. 3a. The temperature dependence of the spectral magnitude further confirms that the 4.4-THz spectral peak is of magnetic origin (see Supplementary Fig. 1). Aside from the 4.4-THz mode, a small peak at 8.9 THz was found. Figure 3c, d show the signed amplitude F j for linear and circular pump polarizations, respectively. F i are almost proportional to cos 2θ for the 4.4-THz and nearly constant for the 8.9-THz modes. In contrast to the TG, the sign of F for the 4.4-THz mode changes by reversing the pump helicity, clearly identifying the IFE28,29,30,31,32.

Fig. 3
Fig. 3

Terahertz magnon modes in the longitudinal geometry. a Change Δf in the probe-light polarization as a function of delay time from the pump light to the probe light at T = 5 K in the longitudinal geometry. Pump pulses were linearly polarized with different values of θ or circularly polarized σ± (ψ = 90°). b Fourier-transformed amplitude spectrum of the result with θ = 0° in (a). The inset shows a magnification of the spectrum. c, d Pump polarization dependence of the signed amplitude F in the 4.4 and 8.9 THz modes fitted by function Δf(t) ≡ FeαΩt sin(Ωt + ϑ). The fitted results of F at 4.4 THz (solid line) and 8.9 THz (dotted line) are shown as functions of θ for linear polarizations (c) and of ψ for circular polarizations (d). The error bars represent the SD of the measurements


We now discuss the symmetry of the magnon modes. Our analysis (see Supplementary Note 3) reveals that the 4.4-THz mode is the Γ2 mode, which is excited with the (1 − cos 2θ)-dependent ICME in the TG (Supplementary Eq. (31)), with the cos 2θ-dependent ICME (Supplementary Eq. (35)) and with the helicity-dependent IFE (Supplementary Eq. (36)) in the LG. The polarization dependences of the 6.6-THz mode in the TG is neither cos 2θ nor (1 − cos 2θ) (Supplementary Eq. (29)) and hence this mode can be interpreted as a Γ1 mode. If the high-frequency signal is caused by an excitation of one pure mode, either Γ1 mode or Γ2 mode, its θ-dependence should follow one of the dependencies observed for low-frequency modes. From the experimental data, this is not evident for the TG. Thus, we suggest that the signal observed at 8.9 THz is a superposition of signals of two excited modes of different symmetries but similar frequencies. Our experimental results indicate that the lower-frequency (4.4 and 6.6 THz) modes with different symmetries have significantly different frequencies, whereas the higher-frequency (8.9 THz) modes with different symmetries are degenerate. This finding contrasts with previous studies in which the low-frequency Γ1 and Γ2 modes were claimed to be almost degenerate13, 15, probably because the samples were not confirmed to be a single domain. Our spontaneous Raman scattering measurements on a single domain support our conclusion (see Supplementary Fig. 2).

Previous theoretical studies on CoO spin–orbit dynamics were based on the quasi-uniaxial models, where the magnetic anisotropy originates mainly from the crystal field having the form \( - C\left( {L_{z,1}^2 + L_{z,2}^2} \right)\) 13,14,15,16,17,18,19. Such models obviously lead to almost-degenerate doublets of the modes with Γ1 and Γ2 symmetries, which is not consistent with our observations. To describe our experimental results, we propose a quantum mechanical model with a biaxial crystal field for states with orbital angular momentum L = 1 (see Supplementary Note 1 for details). For transverse oscillations, four modes of coupled spin–orbit dynamics are found analytically and the parameters of the Hamiltonian are determined. The pair of lower-frequency modes appears to be spin dominated, whereas the almost-degenerate pair of higher-frequency modes is orbital dominated. It is noteworthy that the different degrees of lifting the degeneracy of the lower-frequency and higher-frequency modes require the notion of competing spin and orbital contributions to the anisotropy. See Supplementary Notes 1, 2 for more details.

Here we discuss the reason why the 4.4-THz mode was not excited by the IFE in the TG. In principle, this mode can be excited by the IFE because of the term K 2 in Supplementary Eq. (32), as well as the ICME from term G 4 in Supplementary Eq. (31). The reason why this mode was not excited by the IFE is the following. The 4.4-THz mode is a Γ2(S) mode, where the trajectory of the magnetization vector is an ellipse elongated along the y axis. Excitation by the IFE initializes as a kick on the magnetization along the y direction, whereas that by the ICME is along the x direction, which corresponds to the short axis of the ellipse. Therefore, the ICME dominates the excitation efficiency and the helicity-dependent excitation via the IFE was not observed.

To summarize, we demonstrated that femtosecond laser pulses can efficiently excite magnons consisting of the spin and unquenched orbital angular momentum in CoO. The study of coupled spin–orbital dynamics is of great interest in the promising area of optomagnonics. First, it enables the realization of faster spin dynamics, in particular excitation of magnons with higher frequencies than those mediated by pure spin dynamics. Second, the materials with a large fraction of orbital angular momentum oscillations are expected to exhibit higher efficiency in their magneto-optical effects (either inverse or direct), which leads to higher amplitudes of both excited magnons and of the probe signal. Indeed, we found that CoO produces quite a high magneto-optical signal from the excited magnons even for frequencies of order 10 THz.



The samples were CoO (001) biaxial single crystals33 grown by the floating zone method. Magneto-striction leads to contraction of the cubic unit cell along the 〈100〉 direction and gives rise to three types of T domains34. From the TG- and the LG-configured pump–probe measurements, two types of T domains were classified from observations of differences in birefringence in the cross-Nicol configuration using a polarization microscope. In the TG, its optic axes were 4° out of alignment with the [010] and [001] directions, and \(\Delta n \simeq 0.02\) for 633 nm at 5 K; in the LG, the crystal had axes in the [110] and \([1\bar 10]\) directions, and \(\Delta n \simeq 0.001\). The values agree with those taken from the literature33, 34. The thicknesses of the samples were 70 μm for the TG and 50 μm for the LG.

Pump–probe experimental setup

The samples were cooled at 5 K in a cryostat in the absence of an external magnetic field. A Ti: sapphire regenerative laser amplifier (Spectra-Physics, Spitfire Pro) was used as the fundamental light source producing a central wavelength of 800 nm, a pulse duration of 50 fs and a repetition frequency of 1 kHz. With an optical parametric amplifier, a part of this light was converted to a wavelength of 1,500 nm and used as pump pulses. The pump wavelength was chosen to avoid the real (dd) excitation35. The pump–pulse fluence was 130 mJ cm−2. The rest of the light passed through a delay line before entering the sample as time-delayed probe pulses. To obtain a maximal signal, in the TG, probe pulses were linearly polarized with ϕ = 26.5° from [001] that enabled the simultaneous detection of the FE, CME and linear dichroism, whereas in the LG the probe pulses were linearly polarized at ϕ = 45° (see Supplementary Fig. 3). The change in the probe polarization was obtained by measuring the balance of the two linearly polarized components from the transmitted probe light; these orthogonal components, I 1 and I 2 have the same magnitude. I 1 and I 2 were ±45° from the reference angle when injected into the sample. The transmitted probe pulse was divided into two orthogonally polarized pulses by a Wollaston prism, each pulse was detected using a Si photodiode. We calculated f = (I 1 − I 2)/(I 1 + I 2) and regarded Δf(t) as a modulation of the probe polarization26.

Data availability

Data that support the findings of this study are available from the corresponding author on request.

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We thank H. Tamaru and K. Tomiyasu for valuable discussions, and K. Tsuchida for technical assistance. T. Satoh was supported by JST-PRESTO, JSPS KAKENHI (numbers JP15H05454 and JP26103004), JSPS Core-to-Core Program (A. Advanced Research Networks) and Kyushu University Short-term International Research Visitation Program. T.H. was supported by JSPS Postdoctoral Fellowship for Research Abroad and the European Research Council (Consolidator Grant NearFieldAtto). B.A.I. was supported by JSPS Invitation Fellowship Programs for Research in Japan and the National Academy of Sciences of Ukraine (No. 1/16-N). V.I.B. was supported financially by the Russian Foundation for Basic Research (No. 16-02-00069 a) and the Increase Competitiveness Program of NUST “MISiS” (Act 211 of the Russian Federation, contract number 02.A03.21.001).

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Author notes

  1. Takuya Satoh and Ryugo Iida contributed equally to this work.


  1. Department of Physics, Kyushu University, Fukuoka, 819-0395, Japan

    • Takuya Satoh
  2. Institute of Industrial Science, The University of Tokyo, Tokyo, 153-8505, Japan

    • Takuya Satoh
    • , Ryugo Iida
    • , Tsutomu Shimura
    •  & Kazuo Kuroda
  3. Department of Physics, Friedrich-Alexander-Universität Erlangen-Nürnberg (FAU), 91058, Erlangen, Germany

    • Takuya Higuchi
  4. Department of Physical Sciences, Ritsumeikan University, Shiga, 525-8577, Japan

    • Yasuhiro Fujii
    •  & Akitoshi Koreeda
  5. Department of Chemistry, Kyoto University, Kyoto, 606-8502, Japan

    • Hiroaki Ueda
  6. National University of Science and Technology “MISiS”, Moscow, 119049, Russia

    • V. I. Butrim
  7. Institute of Magnetism, Ukrainian Academy of Science, 03142, Kiev, Ukraine

    • B. A. Ivanov
  8. Taras Shevchenko National University of Kiev, 03127, Kiev, Ukraine

    • B. A. Ivanov


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T. Satoh conceived the project. R.I. and T. Satoh carried out the pump–probe experiment. Y.F., A.K. and T. Satoh measured spontaneous Raman spectra. B.A.I. and V.I.B. performed the model calculation. B.A.I., V.I.B., R.I., T.H. and T. Satoh analyzed the data. H.U. provided the sample. T. Shimura and K.K. supervised the project. T. Satoh, R.I., T.H., B.A.I. and V.I.B. wrote the manuscript. All authors discussed the results and commented on the manuscript.

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The authors declare no competing financial interests.

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Correspondence to Takuya Satoh.

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