Unexpected observation of splitting of skyrmion phase in Zn doped Cu2OSeO3

Hc, Wu; Wei, Tian; Chandrasekhar, K. Devi; Chen, T. Y.; Berger, H.; Yang, H. D.

doi:10.1038/srep13579

Cited by 29 publications

(31 citation statements)

References 33 publications

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“…5(a). χðHÞ exhibits an anomaly between the fields H A1 ¼ 0.14 and H A2 ¼ 0.32 kOe, similar to those observed for skyrmion spin structures in other systems [35][36][37][38][39][40][41][42][43][44][45]. Note that MðHÞ data in Fig.…”

supporting

confidence: 78%

“…The chiral spin structure of B20 magnets is well known to support spin spirals (helices) [4] and skyrmions [1-3, 5,7]. Such noncollinear spin structures can be investigated by analyzing the field dependences of MðHÞ and χ ¼ dMðHÞ=dH, where they give rise to characteristic features or anomalies just below T c in single crystals, thin films and polycrystalline samples, corresponding to skyrmion spin structures [3,[35][36][37][38][39][40][41][42][43][44][45]. The room-temperature field dependences of M and χ for x ¼ 0.043 sample are shown in Fig.…”

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confidence: 99%

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Chiral Magnetism and High-Temperature Skyrmions in B20-Ordered Co-Si

et al. 2020

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Magnets with chiral crystal structures and helical spin structures have recently attracted much attention as potential spin-electronics materials, but their relatively low magnetic-ordering temperatures are a disadvantage. While cobalt has long been recognized as an element that promotes high-temperature magnetic ordering, most Co-rich alloys are achiral and exhibit collinear rather than helimagnetic order. Crystallographically, the B20-ordered compound CoSi is an exception due to its chiral structure, but it does not exhibit any kind of magnetic order. Here, we use nonequilibrium processing to produce B20-ordered Co 1þx Si 1−x with a maximum Co solubility of x ¼ 0.043. Above a critical excess-Co content (x c ¼ 0.028), the alloys are magnetically ordered, and for x ¼ 0.043, a critical temperature T c ¼ 328 K is obtained, the highest among all B20-type magnets. The crystal structure of the alloy supports spin spirals caused by Dzyaloshinskii-Moriya interactions, and from magnetic measurements we estimate that the spirals have a periodicity of about 17 nm. Our density-functional calculations explain the combination of high magneticordering temperature and short periodicity in terms of a quantum phase transition where excess-cobalt spins are coupled through the host matrix.

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confidence: 78%

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confidence: 99%

Chiral Magnetism and High-Temperature Skyrmions in B20-Ordered Co-Si

et al. 2020

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“…Magnetic interactions between spins are mediated through oxygen atoms via ferromagnetic and antiferromagnetic superexchange interactions [23,24]. As reported by Wu et al [17], the magnetic moment of Cu 2 OSeO 3 monotonically decreases with increasing Zn-substitution levels, which they interpret in terms of the site-specific substitution of Cu 2+ cation at the Cu site with nonmagnetic Zn 2+ . This is accompanied by a splitting of the SkL phase observed in pristine Cu 2 OSeO 3 into two distinct pockets.…”

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confidence: 70%

“…An alternative route to expand the number of skyrmionic materials is to utilize a chemical doping/substitution strategy in known skyrmion-hosting systems. This approach has recently been adopted in Cu 2 OSeO 3 , where Zn substitution led to observation of splitting of the skyrmion lattice (SkL) phase into two distinct pockets [17], and Ni substitution led to an expansion of the SkL phase [18].…”

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confidence: 99%

Origin of skyrmion lattice phase splitting in Zn-substitutedCu2OSeO3

Štefančič

Moody

Hicken

et al. 2018

Phys. Rev. Materials

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We present an investigation into the structural and magnetic properties of Zn-substituted Cu 2 OSeO 3 , a system in which the skyrmion lattice (SkL) phase in the magnetic field-temperature phase diagram was previously seen to split as a function of increasing Zn concentration. We find that splitting of the SkL is only observed in polycrystalline samples and reflects the occurrence of several coexisting phases with different Zn content, each distinguished by different magnetic behavior. No such multiphase behavior is observed in single-crystal samples.

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“…Their stability is attributed to the competition between the ferromagnetic exchange, the Dzyaloshinskii-Moriya (DM) and Zeeman interactions in combination with additional small terms, 15 such as thermal fluctuations, 8,16 dipolar interactions and the softening of the magnetization modulus. 17,18 As the free energy imbalance between the skyrmion lattice phase and its main competitor, the conical state, is small, the boundaries of the A-phase can be changed substantially by applying pressure, 19 electric fields, 13,[20][21][22] chemical doping, 23 or uniaxial strains. 24,25 On the other hand, theoretical models that are based on the Dzyaloshinskii approach 26,27 and include magnetic stiffness or anisotropy, predict SkLs to occur in bulk cubic helimagnets over a wide range of magnetic fields and temperatures below T C .…”

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confidence: 99%

Multiple low-temperature skyrmionic states in a bulk chiral magnet

et al. 2019

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Magnetic skyrmions are topologically protected nanoscale spin textures with particle-like properties. In bulk cubic helimagnets, they appear under applied magnetic fields and condense spontaneously into a lattice in a narrow region of the phase diagram just below the magnetic ordering temperature, the so-called A-phase. Theory, however, predicts skyrmions to be locally stable in a wide range of magnetic fields and temperatures. Our neutron diffraction measurements reveal the formation of skyrmion states in large areas of the magnetic phase diagram, from the lowest temperatures up to the A-phase. We show that nascent and disappearing spiral states near critical lines catalyze topological charge changing processes, leading to the formation and destruction of skyrmionic states at low temperatures, which are thermodynamically stable or metastable depending on the orientation and strength of the magnetic field. Skyrmions are surprisingly resilient to high magnetic fields: the memory of skyrmion lattice states persists in the field polarized state, even when the skyrmion lattice signal has disappeared. These findings highlight the paramount role of magnetic anisotropies in stabilizing skyrmionic states and open up new routes for manipulating these quasi-particles towards energy-efficient spintronics applications.

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Unexpected observation of splitting of skyrmion phase in Zn doped Cu2OSeO3

Cited by 29 publications

References 33 publications

Chiral Magnetism and High-Temperature Skyrmions in B20-Ordered Co-Si

Chiral Magnetism and High-Temperature Skyrmions in B20-Ordered Co-Si

Origin of skyrmion lattice phase splitting in Zn-substitutedCu2OSeO3

Multiple low-temperature skyrmionic states in a bulk chiral magnet

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