Magnetic 2D materials and heterostructures

Gibertini, Marco; Koperski, Maciej; Morpurgo, Alberto F.; Novoselov, Kostya S.

doi:10.1038/s41565-019-0438-6

Cited by 1,321 publications

(1,107 citation statements)

References 130 publications

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“…The weak vdWs interlayer force in 2D materials makes it possible to isolate 2D films and restack them into arbitrary stacking heterojunctions without the restriction of the lattice match . By stacking 2D materials with different functions, one can achieve new features that are not available in each individual component.…”

Section: Plasmons In Anisotropic 2d Materialsmentioning

confidence: 99%

The Optical Properties and Plasmonics of Anisotropic 2D Materials

Wang

Zhang

Huang

et al. 2019

Advanced Optical Materials

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In the fast growing 2D materials family, anisotropic 2D materials, with their intrinsic in‐plane anisotropy, exhibit a great potential in optoelectronics. One such typical material is black phosphorus (BP), with a layer‐dependent and highly tunable bandgap. Such intrinsic anisotropy adds a new degree of freedom to the excitation, detection, and control of light. Particularly, hyperbolic plasmons with hyperbolic q‐space dispersion are predicted to exist in BP films, where highly directional propagating polaritons with divergent densities of states are hosted. Combined with a tunable electronic structure, such natural hyperbolic surfaces may enable a series of exotic applications in nanophotonics. Herein, the anisotropic optical properties and plasmons (especially hyperbolic plasmons) of BP are discussed. In addition, other possible 2D material candidates (especially anisotropic layered semimetals) for hyperbolic plasmons are examined. This review may stimulate further research interest in anisotropic 2D materials and fully unleash their potential in flatland photonics.

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Section: Plasmons In Anisotropic 2d Materialsmentioning

confidence: 99%

The Optical Properties and Plasmonics of Anisotropic 2D Materials

Wang

Zhang

Huang

et al. 2019

Advanced Optical Materials

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“…Following the trend of polariton hybrids in hBN/graphene and hBN/phase change materials, more nanophotonic properties are envisioned to be engineered in vdW heterostructures. In particular, atomic plane assembling, twisting and other new schematics can implement intriguing physical properties to hybrid polaritons, including superconductivity, topological protected states, and 2D magnetism 2)Hyperbolic phonon polaritons for emission engineering, nonlinear, and quantum optics.…”

Section: Discussionmentioning

confidence: 99%

“…In particular, atomic plane assembling, twisting and other new schematics can implement intriguing physical properties to hybrid polaritons, including superconductivity, [124,125] topological protected states, [126] and 2D magnetism. [127] 2) Hyperbolic phonon polaritons for emission engineering, nonlinear, and quantum optics. Strong field enhancement, confinement and the boosted optical density of states make hyperbolic phonon polaritonic systems ideal for enhancing the emission and energy transfer.…”

Section: Wwwadvopticalmatdementioning

confidence: 99%

Phonon Polaritons and Hyperbolic Response in van der Waals Materials

Shen

Qiu

et al. 2019

Advanced Optical Materials

100

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Phonon polaritons provide useful opportunities, complementary to those provided by plasmon polaritons, in the study of the interaction of light with matter at small scales. The focus of this review is on phonon polaritons in low‐dimensional van der Waals (vdW) materials and heterostructures. Phonon polaritons confined in vdW materials exhibit large electromagnetic localization and are easy to hybridize with other collective modes. The extreme optical anisotropy in vdW systems produces the natural hyperbolic dispersion, enabling the access to deep subdiffractional optics and often yielding improved figures of merit over hyperbolic metamaterials. These virtues hold promises for practical nanophotonic applications, including optical sensing, super‐resolution imaging, energy and emission engineering, quantum optics, and a next generation of optical circuit elements.

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“…This enables ample opportunities for exciting studies of 2D and monolayer magnetism. Furthermore, the active spins interplay with other electronic degrees of freedom, as well as with exotic quantum phenomena, such as charge density wave (CDW), superconductivity, and topological order . Heterostructures and devices based on 2D‐vdW magnets are expected to possess a great variety of properties with strong application potential.…”

Section: Introductionmentioning

confidence: 99%

Van der Waals magnets: Wonder building blocks for two‐dimensional spintronics?

Zhang

Wong

Zhu

et al. 2019

InfoMat

102

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The unprecedented realization of two‐dimensional (2D) van der Waals magnets excitingly extends the synergy between spintronics and 2D materials, started with graphene over the last decade. This article reviews the recent milestones in the development of 2D magnets and its derived heterostructures. In particular, a number of critical challenges centered around the scalability, ambient stability and Curie temperature of these atomically thin magnets are discussed. This mini‐review also provides an outlook on what the future might hold for this integrated field of 2D spintronics, and assesses its potential in postsilicon electronics.

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Magnetic 2D materials and heterostructures

Cited by 1,321 publications

References 130 publications

The Optical Properties and Plasmonics of Anisotropic 2D Materials

The Optical Properties and Plasmonics of Anisotropic 2D Materials

Phonon Polaritons and Hyperbolic Response in van der Waals Materials

Van der Waals magnets: Wonder building blocks for two‐dimensional spintronics?

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