Erratum: Electric Control of Spin Helicity in a Magnetic Ferroelectric [Phys. Rev. Lett.<b>98</b>, 147204 (2007)]

Yamasaki, Y.; Sagayama, Hajime; Goto, Takayuki; Matsuura, Masato; Hirota, K.; Arima, Taka‐hisa; Tokura, Y.

doi:10.1103/physrevlett.100.219902

Cited by 135 publications

(201 citation statements)

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“…The ferroelectricity in this compound is also of magnetic origin and emerges from a cycloidal spin order, just as in the case of Ni 3 V 2 O 8 . The same questions, that is to know whether the spin helicity was connected to the direction of the spontaneous polarization, and if it was possible to control this sense by an electric field was answered by a slightly different polarized neutron experiment [33]. The authors have investigated this helicity in a simpler setup, using incoming polarized neutrons without subsequent polarization analysis (often called half-polarized experiment in the literature), in a geometry where P i Q.…”

Section: Longitudinal Polarization Analysis (Lpa)mentioning

confidence: 99%

Polarized neutron diffraction

Ressouche

2014

Journées de la Neutronique

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Abstract. This lecture addresses the different applications of polarized neutron diffraction, with or without subsequent polarization analysis, to the determination of magnetic structures, to the separation of magnetic and nuclear contributions and to magnetization distributions mapping. The first sections introduce some of the fundamental equations. Then the problems of magnetic domains, encountered in crystals and of particular importance as soon as polarized neutrons are concerned, are presented. The final sections discuss some of the different ways to use polarized neutron and are illustrated by examples. PREAMBLENeutron scattering has progressed over the last sixty years to become an invaluable tool to probe experimentally condensed matter. As far as magnetism is concerned, this technique has been recognized from the early days as unique. The most widespread use of this tool is of course the determination of magnetic structures using unpolarized beams, that is the determination of the directions in which moments point in a magnetically ordered material. Since the first experiment on MnO by Shull and Smart in 1949 [1] which was an experimental proof of the antiferromagnetism predicted by Néel, thousands of structure determinations have been reported and have revealed much more complicated magnetic arrangements than the simple ferromagnetic or antiferromagnetic cases. The comprehension of the stability of these new structures was and is still at the origin of numerous theoretical developments, leaving the study of magnetic structures completely open.From a theoretical point of view, the neutron spin and the possibility of using polarized neutron beam was taken into account from the very beginning [2-6]. Complete equations of polarization analysis in a neutron scattering experiment were derived as early as 1963 [7,8]. But in comparison to those theoretical advances, experimental possibilities were much longer to appear. In 1959 Nathans et al. demonstrated the huge sensitivity of polarized neutrons to weak magnetic signals, allowing very precise magnetization distribution maps to be drawn [9]. Then it took ten years to Moon, Riste and Koehler to operate in Oak Ridge the first triple axis machine with both incident polarized neutrons and longitudinal polarization analysis capabilities, giving access to many new pieces of information [10]. Another twenty years were necessary until Tasset et al. generalized longitudinal polarization analysis to a completely spherical one [11]. During this time, Maleyev also showed that polarization of neutron beams could allow very precise measurements of the energy exchange in a scattering experiment, leading to the development of the spin echo technique by Mezei [12] and to the numerous applications this technique has today. This is an Open Access article distributed under the terms of the Creative Commons Attribution License 4.0, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

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Section: Longitudinal Polarization Analysis (Lpa)mentioning

confidence: 99%

Polarized neutron diffraction

Ressouche

2014

Journées de la Neutronique

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“…1(a)] due to the magnetoelectric coupling. 33 The strength of the exchange coupling J (we assume J > 0) between the electron spin and the magnetic moments, depending on their distance and the specific hosts, is weak and assumed to be of the order of 1-10 µeV. 20,23 Due to the spiral geometry of the magnetic order, the macroscopic magnetism of the multiferroic insulator is zero, while the exchange coupling still breaks the time-reversal symmetry locally and causes an inhomogeneous Zeeman-like interaction on the quantum-dot spin.…”

Section: Spin-orbit Qubit On a Multiferroic Insulatormentioning

confidence: 99%

“…Different from previous studies, 15,[19][20][21][22][23][24][25] our proposal relies on the inhomogeneous exchange field arising from the multiferroic insulators with a cycloidal spiral magnetic order. [31][32][33][34][35][36] These multiferroic insulators provide a unique opportunity for the design of functional devices owing to the cycloidal spiral magnetic order as well as the magnetoelectric coupling. [36][37][38] In our setup for the spin-orbit qubit, as illustrated in Fig.…”

Section: Introductionmentioning

confidence: 99%

Spin-orbit qubit on a multiferroic insulator in a superconducting resonator

2014

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We propose a spin-orbit qubit in a nanowire quantum dot on the surface of a multiferroic insulator with a cycloidal spiral magnetic order. The spiral exchange field from the multiferroic insulator causes an inhomogeneous Zeeman-like interaction on the electron spin in the quantum dot, producing a spin-orbit qubit. The absence of an external magnetic field benefits the integration of such spin-orbit qubit into high-quality superconducting resonators. By exploiting the Rashba spin-orbit coupling in the quantum dot via a gate voltage, one can obtain an effective spin-photon coupling with an efficient on/off switching. This makes the proposed device controllable and promising for hybrid quantum communications.

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“…The underlying physics is governed by competing exchange and Dzyaloshiskii-Moriya (DM) [33] interactions: The spin-orbital coupling associated with d(p) orbitals of magnetic (oxygen) ions triggers the FE polarization [34,35] P ∝ê ij × (S i × S j ); e ij is a unit vector connecting the sites i and j at which the effective spins S i/j reside (e.g., along the [110] direction for TbMnO 3 ). P is thus linked with the spin order chirality κ = (S i × S j ), offering thus a tool for electrical control of κ because, as shown experimentally [36], P can be steered with an external electric field E (with |E| ∼ 1 kV/cm). Indeed, effects of magnetoelectric coupling (ME) are evident in the dynamical response to moderate E [37][38][39][40][41][42], i.e., phenomena rooted in ME can be driven, and possibly controlled, by moderate external fields.…”

Section: Introductionmentioning

confidence: 99%

Helical multiferroics for electric field controlled quantum information processing

et al. 2014

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Magnetoelectric coupling in helical multiferroics allows us to steer spin order with electric fields. Here we show theoretically that in a helical multiferroic chain quantum information processing as well as quantum phases are highly sensitive to electric (E) field. Applying E field, the quantum state transfer fidelity can be increased and made directionally dependent. We also show that E field transforms the spin-density-wave/nematic or multipolar phases of a frustrated ferromagnetic spin-1 2 chain in chiral phase with a strong magnetoelectric coupling. We find sharp reorganization of the entanglement spectrum as well as a large enhancement of fidelity susceptibility at Ising quantum phase transition from nematic to chiral states driven by electric field. These findings point to a tool for quantum information with low power consumption.

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Erratum: Electric Control of Spin Helicity in a Magnetic Ferroelectric [Phys. Rev. Lett.98, 147204 (2007)]

Cited by 135 publications

References 3 publications

Polarized neutron diffraction

Polarized neutron diffraction

Spin-orbit qubit on a multiferroic insulator in a superconducting resonator

Helical multiferroics for electric field controlled quantum information processing

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