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Heterostructures with magnetism and topology (geometry) are promising materials to realize . However, such materials are challenging to engineer or synthesize. In a new report on Science Advances, Jiazhen Wu and an interdisciplinary research team in the departments of Materials Research, Optoelectronic Science, Â鶹ÒùÔºics, Condensed Matter Research and Advanced Materials in Japan and China, reported the development of natural magnetic . The constructs exhibited controllable magnetic properties while maintaining their topological surface states.

During the process, the materials scientists and physicists gradually weakened the interlayer antiferromagnetic exchange coupling while increasing magnetic layer separation to observe an anomalous . At a temperature below 5K, the phenomenon was well coupled with magnetization to cause i.e., applying an external magnetic field to a ferromagnet causing the alignment of its atomic dipoles. The researchers aim to use the homogeneous with atomically sharp interfaces and intrinsic magnetic properties to study exotic phenomena such as the quantum anomalous Hall effect, and topological (the induction of magnetization by an electric field and the induction of electric polarization by a magnetic field).

In condensed matter physics, magnetic heterostructures have attracted considerable attention to in the developing fields of and (nanoelectronics based on topological structures). For example, well-established deposition techniques that assist thin film growth including , and have accelerated the field to facilitate unique properties such as . For instance, had previously demonstrated core technical capabilities for . However, research developments of magnetic heterostructures remain limited due to associated deposition techniques, hindering wide-ranging studies of unique materials systems. Nevertheless, researchers recently used the transfer method to prepare van der Waals heterostructures intricately .

Researchers had also recently developed heterostructures combined with magnetic layers and topological insulator (TI) layers to states. But the development of an ideal platform to study quantum effects using a homogenous heterostructure containing atomically sharp interfaces and intrinsic magnetic properties remains experimentally elusive. In this work, Wu et al. reported naturally occurring van der Waals heterostructures (MnBi₂Te₄)_m(Bi₂Te₃)_m with controllable magnetic properties and topological surface states (SSs). They prepared single crystals using the (method of crystal growth) and identified variants of the molecules using (XRD) measurements and (STEM). When the research team gradually weakened the interlayer antiferromagnetic (AFM) exchange interactions, the materials converted into a with a ferromagnetic (FM) state stabilized below 5K.

Since the magnetization had an out-of-plane easy axis, the researchers observed an anomalous Hall (AH) effect—well coupled with magnetization. They investigated the nontrivial electronic structures of MnBi₄Te₇ in the bulk and surface using (DFT) calculations to confirm its antiferromagnetic topological insulator (AFM TI) properties. Wu et al. experimentally detected the surface states using (ARPES) measurements and expect the novel material to provide a platform to investigate varied interests in spintronics and topotronics.

For example, the synthetic compound is an intrinsic van der Waals antiferromagnet showing topological nontrivial surface states (SS). Since the two van der Waals materials Bi₂Te₃ and MnBi₂Te₄ demonstrated similar lattice constraints, the researchers were keen to test the possibility of synthesizing natural heterostructures with alternating quintuple atomic layers (QLs) and septuple atomic layers (SLs).

Based on the assumption, the researchers prepared polycrystalline samples relative to the formulation of (MnBi₂Te₄)_m(Bi₂Te₃)_nand formed MnBi₄Te₇ and MnBi₆Te₁₀ using a solid-state reaction route. The research team observed the new heterostructures using (HAADF) and STEM measurements. The atomic resolution images were highly consistent with the crystal structures previously obtained using XRD measurements and aligned with the proposed model. They further confirmed high degrees of crystallinity of the prepared samples using (SAED) patterns.

To test the physical properties, Wu et al. then grew single crystals of MnBi₂Te₄ and MnBi₄Te₇ using a flux-assisted method and found the synthesis to be difficult since the phases only evolved at a . The scientists showed MnBi₄Te₇ to be comparatively more complex due to the presence of both QL and SL (quintuple and septuple) atomic layers. The researchers checked the fresh surface of the samples using and under high vacuum and results indicated the samples to be clean and confirmed the presence of all the proposed elements (manganese [Mn], bismuth [Bi] and tellurium [Te]).

To understand the magnetic structures, Wu et al. next conducted magnetization measurements of the single-crystalline samples MnBi₂Te₄ and MnBi₄Te₇. The two compounds showed contrasting magnetic structures. For additional insight into the electronic structure and topology of MnBi₄Te_7, the research team conducted DFT (density functional theory) calculations using the , which is widely used to study small . The team demonstrated band structures of the bulk MnBi₄Te₇ compound with and without (SOC).

Thereafter, the scientists measured the surface state of MnBi₄Te₇ using ARPES (angle-resolved photoemission spectroscopy) at 20 and 300 K with an of 48 eV similar to a previous investigation. Compared with the calculated results, they observed the measured surface states to be derived mainly from the SL-(septuple atomic layer), although they did not exclude contributions from the QL-(quintuple atomic layer). To explain the observations, the scientists also considered the possibility of the QL/SL surface domain sizes being much smaller than the photon beam spot size employed for spectroscopic (ARPES) analysis.

Wu et al. observed ferromagnetic spin fluctuations in MnBi₄Te₇ above the transition temperature (T_N) and credited them to the results observed within the setup. The results however prompted an open question requiring further investigations. Notably, surface states of the MnBi₄Te₇ were more complex than MnBi₂Te₄ by understanding the surface properties and tunable magnetic properties of the magnetic heterostructures the researchers will ideally be able to explore tunable quantized magnetoelectric phenomena in the future.

Wu et al. also recorded the electrical properties of MnBi₄Te₇ single crystals, which notably differed from the MnBi₂Te₄ variant. The compound had a metallic conductivity with the Hall effect showing a carrier concentration of 2.85 x 10²⁰ cm^-3 at 2 degrees Kelvin. The Hall resistivity had a linear field dependence at high fields to suggest a single carrier in the compound. Wu et al. characterized the anomalous electrical transport properties and magnetic structures of MnBi₄Te₇ single crystals to further show dependence of spin-flip transitions on magnetoresistance.

The associated electrons within the compound underwent a higher scattering rate at magnetoresistance plateaus (high-resistance state) than at a lower or higher magnetic field. The scientists observed that such magnetoresistance plateaus could not survive at higher temperatures (>0.35 K) since thermal activation could potentially destroy antiferromagnetic states prompting the system to enter a ferromagnetic state. Importantly, the plateaus in anomalous Hall conductivity resembled axion insulating states and therefore, the present system could also potentially form a platform to create appropriately tuned . When current flows across the magnetic and nonmagnetic layers in the setup, the magnetoresistance effects can grow much stronger, similar to materials with .

In this way, Jiazhen Wu and colleagues summarized the field- and temperature-dependent magnetic structures of MnBi₄Te₇,indicating the compound as a . Comparatively, they did not observe this competing situation with MnBi₂Te₄. The researchers expect the competing magnetic order of the compounds to induce unexplored quantum topological states. The experimental exotic magnetic structures of the present materials will lead to fundamental interests in magnetism. The work will also provide a new platform for topotronics to realize quantized magnetoelectronic phenomena. The successful isolation of the van der Waals materials will provide both materials scientists and physicists brand new opportunities to study the interplay between magnetism and topology .

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