In article number https://doi.org/10.1002/adfm.201808606, Jianyong Xiang, Hualing Zeng, and co‐workers present a prototype ferroelectric field‐effect transistor consisting of van der Waals interacted atomic layers only. The non‐volatile functionality stems from ultra‐thin α‐In2Se3, an emergent two‐dimensional ferroelectric semiconductor. The binary logic bit “0” and “1” can be encoded and stored in the device with the out‐of‐plane electric polarizations.
Manipulation of spin degree of freedom (DOF) of electrons is the fundamental aspect of spintronic and valleytronic devices. Two-dimensional transition metal dichalcogenides (2D TMDCs) exhibit an emerging valley pseudospin, in which spin-up (-down) electrons are distributed in a +K (-K) valley. This valley polarization gives a DOF for spintronic and valleytronic devices. Recently, magnetic exchange interactions between graphene and magnetic insulator yttrium iron garnet (YIG) have been exploited. However, the physics of 2D TMDCs with YIG have not been shown before. Here we demonstrate strong many-body effects in a heterostructure geometry comprising a MoS monolayer and YIG. High-order trions are directly identified by mapping absorption and photoluminescence at 12 K. The electron doping density is up to ∼10 cm, resulting in a large splitting of ∼40 meV between trions and excitons. The trions exhibit a high circular polarization of ∼80% under optical pumping by circularly polarized light at ∼1.96 eV; it is confirmed experimentally that both phonon scattering and electron-hole exchange interaction contribute to the valley depolarization with temperature; importantly, a magnetoresistance (MR) behavior in the MoS monolayer was observed, and a giant MR ratio of ∼30% is achieved, which is 1 order of magnitude larger than the reported ratio in MoS/CoFeO heterostructures. Our experimental results confirm that the giant MR behaviors are attributed to the interfacial spin accumulation due to YIG substrates. Our work provides an insight into spin manipulation in a heterostructure of monolayer materials and magnetic substrates.
Artificial spin ices are arrays of correlated nano-scale magnetic islands that prove an excellent playground in which to study the role of topology in critical phenomena. Here, we investigate a continuum of spin ice geometries, parameterised by rotation of the islands. In doing so, we morph from the classic square ice to the recently studied pinwheel geometry, with the rotation angle acting as a proxy for controlling inter-island interactions. We experimentally observe a transition from antiferromagnetic ordering in square ice to a slight preference for ferromagnetic vertices in the weakly-coupled pinwheel ice using Lorentz transmission electron microscopy on thermally annealed cobalt arrays. The rotation angle also affects the relaxation timescales for individual arrays, leading to varying degrees of thermalisation, and an apparent change in the nature of the defects supported: from one-dimensional strings in square ice to two-dimensional vortex-like structures for geometries similar to pinwheel. The numerical scaling of these quantities is consistent with that predicted by the Kibble-Zurek mechanism. Our results show how magnetic order in artificial spin ices can be tuned by changes in geometry and suggest the possibility of realising a truly frustrated icerule phase in two-dimensional systems. Furthermore, we demonstrate this system as a testbed to investigate out-of-equilibrium dynamics across phases.
The physics of phase transitions in two-dimensional (2D) systems underpins research in diverse fields including statistical mechanics, nanomagnetism, and soft condensed matter. However, many aspects of 2D phase transitions are still not well understood, including the effects of interparticle potential, polydispersity, and particle shape. Magnetic skyrmions are chiral spin-structure quasi-particles that form two-dimensional lattices. Here, we show, by real-space imaging using in situ cryo-Lorentz transmission electron microscopy coupled with machine learning image analysis, the ordering behavior of Neél skyrmion lattices in van der Waals Fe 3 GeTe 2 . We demonstrate a distinct change in the skyrmion size distribution during field-cooling, which leads to a loss of lattice order and an evolution of the skyrmion liquid phase. Remarkably, the lattice order is restored during field heating and demonstrates a thermal hysteresis. This behavior is explained by the skyrmion energy landscape and demonstrates the potential to control the lattice order in 2D phase transitions.
Magnetic van der Waals (vdW) materials offer an opportunity
to
design heterostructures that will lead to exotic functionalities that
arise from interfacial interaction. In addition to coupling to different
vdW materials, the naturally oxidized surface layer of a vdW material
also forms a heterostructure with its bulk film, giving rise to intriguing
phenomena. Here, we directly observe the impact of oxidation on the
magnetic domains, namely, magnetic stripe domain and skyrmions, in
a nanoscale Fe3GeTe2 flake using cryo Lorentz
transmission electron microscopy. After the Fe3GeTe2 is exposed to ambient conditions, partial oxidation leads
to an increase in the density of skyrmions even under zero magnetic
field. Complete oxidation leads to a loss of the magnetic domain structure.
We observe a gradual change in Fe3GeTe2 from
single crystal to amorphous as the oxidation increases. The oxidized
Fe3GeTe2 primarily consists of iron oxide, which
could be antiferromagnetic in nature. We hypothesize that the interfacial
interaction between these surface antiferromagnetic oxides and the
bulk ferromagnetic Fe3GeTe2, as well as the
effect of interfacial roughness, leads to the increase in Néel
skyrmion creation. This work opens a path to harness controlled oxidation
as a build block to create dense skyrmion lattices without the need
for an external magnetic field, leading to potential future applications
in spintronic devices.
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