Ultrafast giant magnetic cooling effect in ferromagnetic Co/Pt multilayers

Shim, Joongpyo; Syed, Akbar Ali; Kim, Chul-Hoon; Lee, Kyung Min; Park, Seung-Young; Jeong, Jong‐Ryul; Kim, Dong‐Hyun; Kim, Dong Eon

doi:10.1038/s41467-017-00816-w

Cited by 14 publications

(6 citation statements)

References 49 publications

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“…G ee is an energy exchange coefficient between non-thermal and thermal electrons. The K l term describes the thermal diffusion of energy via the lattice, which is modeled to be proportional to the third power of the temperature increase of the lattice system 12,33 .…”

Section: Discussionmentioning

confidence: 99%

“…Photoinduced spin dynamics allows us to control magnetic moments on a femtosecond time scale simply by optical pulses 4,5 , as well as by external field or spin current 6,7 . Since the seminal work on a Ni single layer by Beaurepaire et al 8 , numerous studies have investigated the underlying mechanism of ultrafast photoinduced spin dynamics [9][10][11][12][13] . It has been generally accepted that energy from photons is transferred first into the electron sub-system within a few tens of femtoseconds and hot electrons then transfer their energies into the spin and the lattice sub-systems, leading to a final equilibrium state among electron, spin, and lattice sub-systems [8][9][10] .…”

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confidence: 99%

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Role of non-thermal electrons in ultrafast spin dynamics of ferromagnetic multilayer

Shim

Syed

Kim

et al. 2020

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Understanding of ultrafast spin dynamics is crucial for future spintronic applications. In particular, the role of non-thermal electrons needs further investigation in order to gain a fundamental understanding of photoinduced demagnetization and remagnetization on a femtosecond time scale. We experimentally demonstrate that non-thermal electrons existing in the very early phase of the photoinduced demagnetization process play a key role in governing the overall ultrafast spin dynamics behavior. We simultaneously measured the time-resolved reflectivity (TR-R) and the magneto-optical Kerr effect (TR-MOKE) for a Co/Pt multilayer film. By using an extended three-temperature model (E3TM), the quantitative analysis, including non-thermal electron energy transfer into the subsystem (thermal electron, lattice, and spin), reveals that energy flow from non-thermal electrons plays a decisive role in determining the type I and II photoinduced spin dynamics behavior. Our finding proposes a new mechanism for understanding ultrafast remagnetization dynamics.

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Section: Discussionmentioning

confidence: 99%

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confidence: 99%

Role of non-thermal electrons in ultrafast spin dynamics of ferromagnetic multilayer

Shim

Syed

Kim

et al. 2020

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“…Such spin cooling and spin heating of magnetization can be observed when the external source of angular momentum is a magnetic field 23 , spin-polarized hot electrons 24 – 26 , the spin angular momentum coming from one sublattice in ferrimagnets 27 – 29 or a Ruderman–Kittel–Kasuya–Yosida (RKKY) exchange coupling 30 , 31 . In these cases, however, magnetization was either far from quenched or CSD was still present (see the supporting information in ref.…”

Section: Introductionmentioning

confidence: 99%

Accelerating ultrafast magnetization reversal by non-local spin transfer

et al. 2023

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When exciting a magnetic material with a femtosecond laser pulse, the amplitude of magnetization is no longer constant and can decrease within a time scale comparable to the duration of the optical excitation. This ultrafast demagnetization can even trigger an ultrafast, out of equilibrium, phase transition to a paramagnetic state. The reciprocal effect, namely an ultrafast remagnetization from the zero magnetization state, is a necessary ingredient to achieve a complete ultrafast reversal. However, the speed of remagnetization is limited by the universal critical slowing down which appears close to a phase transition. Here we demonstrate that magnetization can be reversed in a few hundreds of femtoseconds by overcoming the critical slowing down thanks to ultrafast spin cooling and spin heating mechanisms. We foresee that these results outline the potential of ultrafast spintronics for future ultrafast and energy efficient magnetic memory and storage devices. Furthermore, this should motivate further theoretical works in the field of femtosecond magnetization reversal.

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“…[2][3][4] One of the key issues related to the ultrafast spin dynamics of magnetic materials is the demagnetization process. In the transition 3d ferromagnetic metals, [5][6][7][8] the magnetic order was found to be quenched in a sub-picosecond timescale and then re-magnetized in a longer timescale of several picoseconds (ps). In half metals, [9][10][11] such as Sr2FeMoO6, CrO2 and La0.6Sr0.4MnO3, experimental observations have shown that the ultrafast demagnetization involves two steps: an initial instantaneous decrease within a ps and a subsequent slow decreasing response lasting for several hundreds of ps.…”

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“…However, the transient enhancement of the magnetization observed with s-polarized probe light cannot be expected from the thermal process, which should lead to an instantaneous drop rather than increase in magnetization as previously reported. [8] Considering the strongly coupled degrees of freedom between the spin and orbital in the LSMO film, we expect that the orbital orientation plays a role in the magnetization enhancement. To verify this assumption, we have investigated the effect of the probe light polarization orientation on the pump-induced spin dynamics.…”

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Ultrafast Orbital‐Oriented Control of Magnetization in Half‐Metallic La_0.7Sr_0.3MnO₃ Films

et al. 2019

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Manipulating spins by ultrafast pulse laser provides a new avenue to switch the magnetization for spintronic applications. While the spin–orbit coupling is known to play a pivotal role in the ultrafast laser‐induced demagnetization, the effect of the anisotropic spin–orbit coupling on the transient magnetization remains an open issue. This study uncovers the role of anisotropic spin–orbit coupling in the spin dynamics in a half‐metallic La0.7Sr0.3MnO3 film by ultrafast pump–probe technique. The magnetic order is found to be transiently enhanced or attenuated within the initial sub‐picosecond when the probe light is tuned to be s‐ or p‐polarized, respectively. The subsequent slow demagnetization amplitude follows the fourfold symmetry of the orbitals as a function of the polarization angles of the probe light. A model based on the Elliott–Yafet spin‐flip scatterings is proposed to reveal that the transient magnetization enhancement is related to the spin‐mixed states arising from the anisotropic spin–orbit coupling. The findings provide new insights into the spin dynamics in magnetic systems with anisotropic spin–orbit coupling as well as perspectives for the ultrafast control of information process in spintronic devices.

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Ultrafast giant magnetic cooling effect in ferromagnetic Co/Pt multilayers

Cited by 14 publications

References 49 publications

Role of non-thermal electrons in ultrafast spin dynamics of ferromagnetic multilayer

Role of non-thermal electrons in ultrafast spin dynamics of ferromagnetic multilayer

Accelerating ultrafast magnetization reversal by non-local spin transfer

Ultrafast Orbital‐Oriented Control of Magnetization in Half‐Metallic La_0.7Sr_0.3MnO₃ Films

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Ultrafast giant magnetic cooling effect in ferromagnetic Co/Pt multilayers

Cited by 14 publications

References 49 publications

Role of non-thermal electrons in ultrafast spin dynamics of ferromagnetic multilayer

Role of non-thermal electrons in ultrafast spin dynamics of ferromagnetic multilayer

Accelerating ultrafast magnetization reversal by non-local spin transfer

Ultrafast Orbital‐Oriented Control of Magnetization in Half‐Metallic La0.7Sr0.3MnO3 Films

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Product

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Ultrafast Orbital‐Oriented Control of Magnetization in Half‐Metallic La_0.7Sr_0.3MnO₃ Films