Room-temperature skyrmion lattice in a layered magnet (Fe
 0.5
 Co
 0.5
 )
 5
 GeTe
 2

Zhang, Hongrui; Raftrey, David; Chan, Ying-Ting; Shao, Yu‐Tsun; Chen, Rui; Chen, Xiang; Huang, Xiaoxi; Reichanadter, Jonathan; Dong, Kaichen; Susarla, Sandhya; Caretta, Lucas; Chen, Zhen; Yao, Jie; Fischer, Peter; Neaton, Jeffrey B.; Wu, Weida; Muller, David A.; Birgeneau, R. J.; Ramesh, R.

doi:10.1126/sciadv.abm7103

Cited by 70 publications

(67 citation statements)

References 68 publications

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“…[1] Since the discovery of intrinsic 2D magnetism in van der Waals (vdW) materials, [17,18] layered magnets have become attractive platforms for spintronics. Magnetic skyrmions have been successfully created in Cr 2 Ge 2 Te 6 , Fe 3 GeTe 2 , and Fe 5 GeTe 2 , [13,[19][20][21][22][23] whereas the room-temperature THE were rarely reported. Recent studies reported the THE-like bumps and dips in Fe 3 GeTe 2 , [24,25] while it needs the magnetic field to be applied along a different crystallographic direction from the one for skyrmion creation.…”

Section: Introductionmentioning

confidence: 99%

Room‐Temperature Magnetic Skyrmions and Large Topological Hall Effect in Chromium Telluride Engineered by Self‐Intercalation

et al. 2022

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physical and materials science, but also because of their great potential for energyefficient spintronic applications. [1,2] Blochtype skyrmions were first observed in B20 magnets, [3,4] where the broken inversion symmetry allows for a Dzyaloshinskii-Moriya interaction (DMI), [5,6] leading to the helical alignment of spins. Similarly, in magnetic multilayers, the broken inversion symmetry along the stacking direction also results in an interfacial DMI, stabilizing Néel-type skyrmions. [7] It has also been demonstrated that skyrmions can be created in certain ferromagnets even without significant DMI, stabilized instead by the competition among the uniaxial magnetic anisotropy, dipolar, and exchange interaction. [8][9][10][11][12][13][14][15] For future spintronic devices in which skyrmions are used as information carriers, electrical detection of skyrmions is crucial. At the adiabatic limit, itinerant spins passing through a skyrmion capture an extra Berry phase. As a result, a transverse Hall voltage will be induced in addition to the ordinary and anomalous Hall effects, known as the topological Hall effect (THE). [16] The topological Hall voltage is proportional to the topological charge (skyrmion number) Room-temperature magnetic skyrmion materials exhibiting robust topological Hall effect (THE) are crucial for novel nano-spintronic devices. However, such skyrmion-hosting materials are rare in nature. In this study, a self-intercalated transition metal dichalcogenide Cr 1+x Te 2 with a layered crystal structure that hosts room-temperature skyrmions and exhibits large THE is reported. By tuning the self-intercalate concentration, a monotonic control of Curie temperature from 169 to 333 K and a magnetic anisotropy transition from outof-plane to the in-plane configuration are achieved. Based on the intercalation engineering, room-temperature skyrmions are successfully created in Cr 1.53 Te 2 with a Curie temperature of 295 K and a relatively weak perpendicular magnetic anisotropy. Remarkably, a skyrmion-induced topological Hall resistivity as large as ≈106 nΩ cm is observed at 290 K. Moreover, a sign reversal of THE is also found at low temperatures, which can be ascribed to other topological spin textures having an opposite topological charge to that of the skyrmions. Therefore, chromium telluride can be a new paradigm of the skyrmion material family with promising prospects for future device applications.

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Section: Introductionmentioning

confidence: 99%

Room‐Temperature Magnetic Skyrmions and Large Topological Hall Effect in Chromium Telluride Engineered by Self‐Intercalation

et al. 2022

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“…Moreover, room‐temperature skyrmion lattice has recently been observed in Co‐doped Fe 5 GeTe 2 . [ 84 ] The doping of Co atoms changes the crystal structure to the P 6 3 mc space group, resulting in the DMI and Néel‐type skyrmions. Another recent study reported a record high T c of 478 K in Ni‐doped Fe 5 GeTe 2 .…”

Section: Resultsmentioning

confidence: 99%

Magnetic Skyrmions with Unconventional Helicity Polarization in a Van Der Waals Ferromagnet

et al. 2022

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Skyrmion helicity, which defines the spin swirling direction, is a fundamental parameter that may be utilized to encode data bits in future memory devices. Generally, in centrosymmetric ferromagnets, dipole skyrmions with helicity of −π/2 and π/2 are degenerate in energy, leading to equal populations of both helicities. On the other hand, in chiral materials where the Dzyaloshinskii–Moriya interaction (DMI) prevails and the dipolar interaction is negligible, only a preferred helicity is selected by the type of DMI. However, whether there is a rigid boundary between these two regimes remains an open question. Herein, the observation of dipole skyrmions with unconventional helicity polarization in a van der Waals ferromagnet, Fe5−δGeTe2, is reported. Combining magnetometry, Lorentz transmission electron microscopy, electrical transport measurements, and micromagnetic simulations, the short‐range superstructures in Fe5−δGeTe2 resulting in a localized DMI contribution, which breaks the degeneracy of the opposite helicities and leads to the helicity polarization, is demonstrated. Therefore, the helicity feature in Fe5−δGeTe2 is controlled by both the dipolar interaction and DMI that the former leads to Bloch‐type skyrmions with helicity of ±π/2 whereas the latter breaks the helicity degeneracy. This work provides new insights into the skyrmion topology in van der Waals materials.

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“…[ 171 ] In addition, its broken inversion symmetry gives rise to Néel‐type skyrmions. [ 172 ] Considering the successful large‐scale epitaxial growth of Fe 3 GeTe 2 and Fe 5 GeTe 2 , [ 177,178 ] wafer‐sized (Fe 0.5 Co 0.5 ) 5− x GeTe 2 may be achieved using a similar approach because of the similarity in their in‐plane lattice parameters.…”

Section: Methodsmentioning

confidence: 99%

“…Recently, Zhang et al [ 171 ] reported a 2D polar ferromagnet, (Fe 0.5 Co 0.5 ) 5− x GeTe 2 , with a Curie temperature of ≈350 K. Notably, Néel‐type skyrmions were observed in this material at room temperature. [ 172 ] The findings on room‐temperature skyrmions in 2D magnets pave the way for skyrmion‐based 2D IMDs. Although related research remains in its infancy, the great potential of magnetic skyrmions opens an interesting perspective for future exploration of emerging memories based on 2D magnets.…”

Section: Imds: Mechanisms Architectures and Applicationsmentioning

confidence: 99%

“…[102] However, downscaling of skyrmion-based IMDs seems to be more challenging. On one hand, the skyrmion size in 2D ferromagnets is typically on the order of hundreds of nanometers, [163,165,172] making them uncompetitive with conventional magnetic multilayers or bulk materials for size scaling. [191] On the other hand, the formation of skyrmions is a result of the competition among various magnetic interactions, including magnetic anisotropy and the dipolar interaction.…”

Section: Scalabilitymentioning

confidence: 99%

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Integrated Memory Devices Based on 2D Materials

Xue

Zhang

et al. 2022

Advanced Materials

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With the advent of the Internet of Things and big data, massive data must be rapidly processed and stored within a short timeframe. This imposes stringent requirements on memory hardware implementation in terms of operation speed, energy consumption, and integration density. To fulfill these demands, 2D materials, which are excellent electronic building blocks, provide numerous possibilities for developing advanced memory device arrays with high performance, smart computing architectures, and desirable downscaling. Over the past few years, 2D‐material‐based memory‐device arrays with different working mechanisms, including defects, filaments, charges, ferroelectricity, and spins, have been increasingly developed. These arrays can be used to implement brain‐inspired computing or sensing with extraordinary performance, architectures, and functionalities. Here, recent research into integrated, state‐of‐the‐art memory devices made from 2D materials, as well as their implications for brain‐inspired computing are surveyed. The existing challenges at the array level are discussed, and the scope for future research is presented.

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Room-temperature skyrmion lattice in a layered magnet (Fe _0.5 Co _0.5 ) ₅ GeTe ₂

Cited by 70 publications

References 68 publications

Room‐Temperature Magnetic Skyrmions and Large Topological Hall Effect in Chromium Telluride Engineered by Self‐Intercalation

Room‐Temperature Magnetic Skyrmions and Large Topological Hall Effect in Chromium Telluride Engineered by Self‐Intercalation

Magnetic Skyrmions with Unconventional Helicity Polarization in a Van Der Waals Ferromagnet

Integrated Memory Devices Based on 2D Materials

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Room-temperature skyrmion lattice in a layered magnet (Fe 0.5 Co 0.5 ) 5 GeTe 2

Cited by 70 publications

References 68 publications

Room‐Temperature Magnetic Skyrmions and Large Topological Hall Effect in Chromium Telluride Engineered by Self‐Intercalation

Room‐Temperature Magnetic Skyrmions and Large Topological Hall Effect in Chromium Telluride Engineered by Self‐Intercalation

Magnetic Skyrmions with Unconventional Helicity Polarization in a Van Der Waals Ferromagnet

Integrated Memory Devices Based on 2D Materials

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Product

Resources

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Room-temperature skyrmion lattice in a layered magnet (Fe _0.5 Co _0.5 ) ₅ GeTe ₂