Atomically Thin 2D van der Waals Magnetic Materials: Fabrications, Structure, Magnetic Properties and Applications

He, Wei; Kong, Lingling; Zhao, Weina; Yu, Peng

doi:10.3390/coatings12020122

Cited by 8 publications

(7 citation statements)

References 225 publications

(291 reference statements)

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“…Despite the fair number of reviews already published on this topic as cited above, [ 12–33 ] we present an updated review motivated by the rapid pace of advancement in this field and a number of more recent and important new developments, ranging from new experimental methods to new or less reviewed properties (e.g., magnetic, superconducting, electrochemical) explored in strain engineering. In this review, we summarized and discussed recently reported new methods to induce strain, updated the latest developments on the modification of electrical, magnetic, and optical properties of 2D materials by strain engineering, and presented future perspectives.…”

Section: Introductionmentioning

confidence: 99%

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Recent Progress in Strain Engineering on Van der Waals 2D Materials: Tunable Electrical, Electrochemical, Magnetic, and Optical Properties

Sadi

et al. 2023

Advanced Materials

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counterparts. [2] Therefore, 2D materials are ideal for flexible optoelectronics and have the potential to be used in the next-generation ultrathin electronic and optoelectronic devices. [1] The concept of 2D materials was first realized when graphene was found in 2004. [4] Graphene has attracted extensive attention for its excellent electrical, optical, and mechanical properties. [4][5][6] They have been investigated for various technological applications, including spintronics, sensors, optoelectronics, supercapacitors, and solar cells, etc. [5,7] Besides graphene, other 2D materials, such as h-BN, phosphorene, silicene, germanene, and transition metal dichalcogenides (molybdenum disulfide (MoS 2 ), molybdenum diselenide (MoSe 2 ), tungsten disulfide (WS 2 ), and tungsten diselenide (WSe 2 ), etc.), have been studied extensively in recent years. [1,[8][9][10][11] The thickness of single-layer 2D materials is usually on the order or less than 1 nm. At the same time, their lateral sizes could reach much larger size (from microns to even inches), and 2D materials can be transferred to different substrates before subsequent processing or follow-up measurements for characterizations or device applications.Strain engineering is a promising way to tune the electrical, electrochemical, magnetic, and optical properties of 2D materials, with the potential to achieve high-performance 2D-material-based devices ultimately. This review discusses the experimental and theoretical results from recent advances in the strain engineering of 2D materials. Some novel methods to induce strain are summarized and then the tunable electrical and optical/optoelectronic properties of 2D materials via strain engineering are highlighted, including particularly the previously less-discussed strain tuning of superconducting, magnetic, and electrochemical properties. Also, future perspectives of strain engineering are given for its potential applications in functional devices. The state of the survey presents the ever-increasing advantages and popularity of strain engineering for tuning properties of 2D materials. Suggestions and insights for further research and applications in optical, electronic, and spintronic devices are provided.

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Section: Introductionmentioning

confidence: 99%

“…Given the promising application of strain engineering of 2D materials, there have emerged increasing number of research studies and review papers on this topic. [ 12–33 ] For example, Guinea [ 29 ] reviewed strain engineering on the electronic properties of graphene. Bissett et al.…”

Section: Introductionmentioning

confidence: 99%

Recent Progress in Strain Engineering on Van der Waals 2D Materials: Tunable Electrical, Electrochemical, Magnetic, and Optical Properties

Sadi

et al. 2023

Advanced Materials

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“…Reports of real‐space direct imaging of the magnetic domain structures in vdW ferromagnets have been limited, however, as many of the materials have a low Curie temperature ( T c ), weak magnetic moments, or are otherwise difficult to image because of compensated spin structures or sample volatility and degradation. [ 19 ] Direct imaging is especially important for emergent non‐trivial spin structures, such as skyrmions and merons, which have been reported in similar materials, namely Fe 3 GeTe 2 [ 20 ] and Fe 5 GeTe 2 , [ 21 ] because the relevant length scale of these features is often less than 100 nm. These materials display magnetic bubbles and Néel skyrmions which arise from an interfacial Dzyaloshinskii Moriya interaction (DMI) and can have a relatively high Curie temperature of 220 K. [ 20,22,23 ]…”

Section: Introductionmentioning

confidence: 99%

Direct Observation of Magnetic Bubble Lattices and Magnetoelastic Effects in van der Waals Cr₂Ge₂Te₆

McCray

Qian

et al. 2023

Adv Funct Materials

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Ferromagnetic van der Waals (vdW) materials are of large current interest for the fundamental study of low‐dimensional magnetism and for potential applications in multilayer heterostructures. Cr2Ge2Te6 (CGT) is particularly exciting because it is a ferromagnetic semiconductor with tunable electronic and magnetic properties. Controlling the magnetic domain structure of CGT is a requirement for understanding its novel interface physics and for tuning behavior for potential devices. Herein, cryo‐Lorentz transmission electron microscopy is performed in the temperature range of 12–50K to directly image the magnetic domain structures in CGT. A rich phase diagram of domain structures including stripe domains, magnetic bubble lattices of mixed‐chirality, and topologically‐protected lattices of homochiral magnetic bubbles is observed. The types and chiralities of the bubbles can be controlled by topographical changes in the CGT flakes. Additionally, it is observed that in‐plane strain and magnetoelastic coupling can align and organize both bubble lattices and stripe domains. This study provides insights into creating and controlling complex magnetic domain structures for integration into multilayer heterostructures and for future studies of 2D magnetism.

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“…There is always a challenge to achieving 2D magnetism intrinsically, as most of the synthesized 2D materials are nonmagnetic. With the introduction of anisotropy or by doping incorporation or quantum confinement, magnetism can be induced in nonmagnetic 2D systems. − However, such systems have limited practical applications as the enabled magnetism is generally not robust . In this regard, few MXenes, along with some monolayer magnets, for example, CrI 3 and VSe 2 , are becoming the research focus in the materials science community due to their inherent magnetic property.…”

Section: Introductionmentioning

confidence: 99%

Surface Oxygen Passivation-Driven Large Anomalous Hall Conductivity in Early Transition Metal-Based Nitride MXenes: Can AHC Be a Tool to Determine Functional Groups in 2D Ferro(i)magnets?

2022

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Identifying the existence of specific functional groups in MXenes is a difficult topic that has perplexed researchers for a long time. At the same time, the realization of intrinsic ferromagnetism, which is important for two-dimensional (2D) materials’ families, is one of the fascinating properties that MXenes offer. Here, using first-principle calculations, we have examined the actual magneto-transport phenomena in transition metals and nitride-based-functionalized MXenes. We demonstrate that intrinsic anomalous Hall conductivity (AHC) can be used to identify the presence of more probable functional groups. The maximum AHC at Fermi energy, E F, is found in the case of Mn2NO2 (470 S/cm), which is attributed to the presence of avoided band crossing and a larger density of states. Together, when considering all the studied systems, the AHC can be above 2500 S/cm within E F± 0.25 eV. Our findings could be useful not only in guiding the experimentalists by considering AHC as a possible tool in determining the most probable functional groups in 2D ferro(i)magnets but also in designing memory devices with negligible stray fields.

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Atomically Thin 2D van der Waals Magnetic Materials: Fabrications, Structure, Magnetic Properties and Applications

Cited by 8 publications

References 225 publications

Recent Progress in Strain Engineering on Van der Waals 2D Materials: Tunable Electrical, Electrochemical, Magnetic, and Optical Properties

Recent Progress in Strain Engineering on Van der Waals 2D Materials: Tunable Electrical, Electrochemical, Magnetic, and Optical Properties

Direct Observation of Magnetic Bubble Lattices and Magnetoelastic Effects in van der Waals Cr₂Ge₂Te₆

Surface Oxygen Passivation-Driven Large Anomalous Hall Conductivity in Early Transition Metal-Based Nitride MXenes: Can AHC Be a Tool to Determine Functional Groups in 2D Ferro(i)magnets?

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Atomically Thin 2D van der Waals Magnetic Materials: Fabrications, Structure, Magnetic Properties and Applications

Cited by 8 publications

References 225 publications

Recent Progress in Strain Engineering on Van der Waals 2D Materials: Tunable Electrical, Electrochemical, Magnetic, and Optical Properties

Recent Progress in Strain Engineering on Van der Waals 2D Materials: Tunable Electrical, Electrochemical, Magnetic, and Optical Properties

Direct Observation of Magnetic Bubble Lattices and Magnetoelastic Effects in van der Waals Cr2Ge2Te6

Surface Oxygen Passivation-Driven Large Anomalous Hall Conductivity in Early Transition Metal-Based Nitride MXenes: Can AHC Be a Tool to Determine Functional Groups in 2D Ferro(i)magnets?

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Direct Observation of Magnetic Bubble Lattices and Magnetoelastic Effects in van der Waals Cr₂Ge₂Te₆