Joolee Son scite author profile

The Berry curvature dipole is a physical quantity that is expected to allow various quantum geometrical phenomena in a range of solid-state systems. Monolayer transition metal dichalcogenides provide an exceptional platform to modulate and investigate the Berry curvature dipole through strain. Here we theoretically demonstrate and experimentally verify for monolayer MoS2 the generation of valley orbital magnetization as a response to an in-plane electric field due to the Berry curvature dipole. The measured valley orbital magnetization shows excellent agreement with the calculated Berry curvature dipole which can be controlled by the magnitude and direction of strain. Our results show that the Berry curvature dipole acts as an effective magnetic field in current-carrying systems, providing a novel route to generate magnetization.Berry curvature is central to various topological phenomena observed in solid-state crystals [1], ultracold atoms [2, 3] and photonic architectures [4]. In view of charge transport, its effect has been assumed to be limited to magnetic systems with broken time reversal symmetry as hallmarked by the anomalous Hall effect [5]. Recent theories, however, demonstrated that in nonlinear regime, Hall effect can occur even in time-reversal symmetric systems if they are noncentrosymmetric and possess reduced symmetry (e.g., only one mirror plane) [6,7]. The nonlinear Hall effect has been attributed to the dipole moment formation of the Berry curvature in momentum space. Such Berry curvature dipole widens the scope of Berry curvature effects. It was recently proposed that in transition metal dichalcogenides (TMDs), the Berry curvature dipole may be generated when spatial symmetries of TMDs are lowered by strain [6,8]. This motivates monolayer TMDs as promising materials venue to examine the Berry curvature dipole. As exemplified by ultracold gases, where the in-depth examination of the Berry curvature effects becomes possible through the Berry curvature variation by the optical lattice modulation [2,3], the mechanical tunability of the Berry curvatures in TMDs provides an ideal avenue to explore the Berry curvature dipole.TMDs are noncentrosymmetric two dimensional materials and have two nonequivalent K and K valleys holding the opposite signs of the Berry curvature [9] ( Fig.

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Air-Stable and Layer-Dependent Ferromagnetism in Atomically Thin van der Waals CrPS₄

Son

Park

et al. 2021

ACS Nano

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Ferromagnetism in two-dimensional materials presents a promising platform for the development of ultrathin spintronic devices with advanced functionalities. Recently discovered ferromagnetic van der Waals crystals such as CrI3, readily isolated two-dimensional crystals, are highly tunable through external fields or structural modifications. However, there remains a challenge because of material instability under air exposure. Here, we report the observation of an air-stable and layer-dependent ferromagnetic (FM) van der Waals crystal, CrPS4, using magneto-optic Kerr effect microscopy. In contrast to the antiferromagnetic (AFM) bulk, the FM out-of-plane spin orientation is found in the monolayer crystal. Furthermore, alternating AFM and FM properties observed in even and odd layers suggest robust antiferromagnetic exchange interactions between layers. The observed ferromagnetism in these crystals remains resilient even after the air exposure of about a day, providing possibilities for the practical applications of van der Waals spintronics.

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Air Stable and Layer Dependent Ferromagnetism in Atomically Thin van der Waals CrPS$_{4}$

Son¹,

Son²,

Park³

et al. 2021

Preprint

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Joolee Son

Strain Engineering of the Berry Curvature Dipole and Valley Magnetization in Monolayer MoS2

Air-Stable and Layer-Dependent Ferromagnetism in Atomically Thin van der Waals CrPS₄

Air Stable and Layer Dependent Ferromagnetism in Atomically Thin van der Waals CrPS$_{4}$

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Joolee Son

Strain Engineering of the Berry Curvature Dipole and Valley Magnetization in Monolayer MoS2

Air-Stable and Layer-Dependent Ferromagnetism in Atomically Thin van der Waals CrPS4

Air Stable and Layer Dependent Ferromagnetism in Atomically Thin van der Waals CrPS$_{4}$

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Air-Stable and Layer-Dependent Ferromagnetism in Atomically Thin van der Waals CrPS₄