All-optical spin switching: A new frontier in femtomagnetism — A short review and a simple theory

Zhang, G. P.; Latta, Tanner; Babyak, Z.; Bai, Yihua; George, Thomas F.

doi:10.1142/s0217984916300052

Cited by 38 publications

(50 citation statements)

References 118 publications

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“…To start with, we note that all-optical spin reversal is an optical process and must follow the dipole selection rule. Consider a laser field propagating along the −z axis toward a sample surface [28,32] (see Fig. 1),…”

Section: A Optical Selection Rulementioning

confidence: 99%

“…Over the years, the explanation progresses from the inverse Faraday effect [10,19], Raman scattering [20,21], magnetic circular dichroism [22], pure heating [16], and sublattice spin exchange [23], to ultrafast exchange scattering [24], with new theories emerging in ferromagnets [25][26][27]. This raises a serious question whether a big picture is missing from the existing theories [28]. Furthermore, no theory ever addresses a design protocol for future photospintronic devices based on AOS technology [29].…”

Section: Introductionmentioning

confidence: 99%

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First-principles and model simulation of all-optical spin reversal

et al. 2017

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All-optical spin switching is a potential trailblazer for information storage and communication at an unprecedented fast rate and free of magnetic fields. However, the current wisdom is largely based on semiempirical models of effective magnetic fields and heat pulses, so it is difficult to provide high-speed design protocols for actual devices. Here, we carry out a massively parallel first-principles and model calculation for thirteen spin systems and magnetic layers, free of any effective field, to establish a simpler and alternative paradigm of laser-induced ultrafast spin reversal and to point out a path to a full-integrated photospintronic device. It is the interplay of the optical selection rule and sublattice spin orderings that underlines seemingly irreconcilable helicity-dependent/independent switchings. Using realistic experimental parameters, we predict that strong ferrimagnets, in particular, Laves phase C15 rare-earth alloys, meet the telecommunication energy requirement of 10 fJ, thus allowing a cost-effective subpicosecond laser to switch spin in the GHz region.Comment: 23 pages, 6 figures and one tabl

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Section: A Optical Selection Rulementioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

First-principles and model simulation of all-optical spin reversal

et al. 2017

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“…Most simulations have been phenomenological, 6 where laser fields are treated as an effective magnetic field. 13 Ostler et al 6 and Mentink et al 53 showed that in GdFeCo, HID-AOS and HD-AOS depend on the laser intensity (electric field squared), not the field helicity. As shown in our recent study, 54 caution must be taken if the system has two spin sublattices.…”

Section: Dynamical Simulationmentioning

confidence: 99%

“…As discussed above, the majority of theoretical research has been phenomenological. 13 This calls for a systematic experimental investigation by tuning both system-and laser-specific parameters. Before one can pin down the origin of AOS, it is necessary to develop a many-to-one correspondence between the proposed mechanisms (see Table 1) and more fundamental interactions.…”

Section: Simple Theory For All-optical Switchingmentioning

confidence: 99%

Understanding all-optical spin switching: Comparison between experiment and theory

Zhang

Murakami

et al. 2018

Mod. Phys. Lett. B

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Information technology depends on how one can control and manipulate signals accurately and quickly. Transistors are at the core of modern technology and are based on electron charges. But as the device dimension shrinks, heating becomes a major problem. The spintronics explores the spin degree of electrons and thus bypasses the heat, at least in principle. For this reason, spin-based technology offers a possible solution. In this review, we survey some of latest developments in all-optical switching (AOS), where ultrafast laser pulses are able to reverse spins from one direction to the other deterministically. But AOS only occurs in a special group of magnetic samples and within a narrow window of laser parameters. Some samples need multiple pulses to switch spins, while others need a single-shot pulse. To this end, there are several models available, but the underlying mechanism is still under debate. This review is different from other prior reviews in two aspects. First, we sacrifice the completeness of reviewing existing studies, while focusing on a limited set of experimental results that are highly reproducible in different labs and provide actual switched magnetic domain images. Second, we extract the common features from existing experiments that are critical to AOS, without favoring a particular switching mechanism. We emphasize that given the limited experimental data, it is really premature to identify a unified mechanism. We compare these features with our own model prediction, without resorting to a phenomenological scheme. We hope that this review serves the broad readership well.

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“…In our model, we add a twist by replacing the tight-binding term by a real-space kinetic energy and potential energy term, so we can easily include one extra term, spin-orbit interaction. With these conditions in mind, we have the Hamiltonian as [37][38][39][40][41],…”

Section: Theoretical Formalismmentioning

confidence: 99%

Spin-orbit torque-mediated spin-wave excitation as an alternative paradigm for femtomagnetism

Zhang

Murakami

Bai

et al. 2019

Journal of Applied Physics

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Laser-induced femtosecond demagnetization, femtomagnetism, offers a potential route to develop faster magnetic storage devices. It is generally believed that the traditional spin-wave theory, which is developed for thermally driven slow demagnetization, can not explain this rapid demagnetization by design. Here we show that this traditional spin-wave theory, once augmented by laser-induced spin-orbit torque, provides a highly efficient paradigm for demagnetization, by capturing lowenergy spin-wave excitation that is absent in existing mechanisms. Our paradigm is different from existing ones, but does not exclude them. Microscopically, we find that optical spin-orbit torque generates massive spin waves across several hundred lattice sites, collapsing the long-range spin-spin correlation within 20 fs. Our finding does not only explain new experiments, but also establishes an alternative paradigm for femtomagnetism. It is expected to have far-reaching impacts on future research.

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All-optical spin switching: A new frontier in femtomagnetism — A short review and a simple theory

Cited by 38 publications

References 118 publications

First-principles and model simulation of all-optical spin reversal

First-principles and model simulation of all-optical spin reversal

Understanding all-optical spin switching: Comparison between experiment and theory

Spin-orbit torque-mediated spin-wave excitation as an alternative paradigm for femtomagnetism

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