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The anomalous Hall effect and anomalous Nernst effect are signature transport features for exploring the physics of magnetic topological phases. Here, an anomalous Nernst effect of 1.8 ≈μV/K and an unconventional anomalous Hall effect which does not scale with the magnetization are observed in a metallic tetragonal antiferromagnet.
Replicating the structure of natural systems is an effective approach for designing high-performance materials. Here, the structure of leak leaves is replicated in cellulose-based films, achieving optical transmittance and hydrophobicity for self-cleaning perovskite solar cells.
In-plane anisotropy of electrical conductance in 2D materials is an important element in engineering 2D devices. Here, the charge transport anisotropy at the metal contacts of hBN-encapsulated ReS2 field-effect transistors is investigated, revealing a substantial contact anisotropy ratio of up to 70 at 77 K.
Understanding the influence of spider dragline silk sequence on its properties is important for controlling their strength and toughness properties. Here, a deep-learning framework is proposed that describes the behavior of spider dragline silks, linking sequence and mechanics.
The presence of flat bands near the Fermi energy may lead to an increase in electron correlations and result in unconventional states. Here, non-Fermi liquid behavior and anomalous superconductivity, with a nonmonotonic two-dome-like doping dependence, are observed in Sc2Ir4-xSix and attributed to spin-orbit-coupling driven flat bands.
Thermally conductive nanomaterials are promising for applications in thermal management. Here, morphological control of the van der Waals contact between carbon nanotubes, by adjustment of contact positions, overlapping length, and crossing angles, allows the authors to elucidate the interfacial thermal transport and optimize heat flow at the nanoscale.
Hot-cracking during laser additive manufacturing of high-strength aluminum alloys is a common issue. Here, crack resistance is improved by approximately 50% by using a pulsed laser with ramp-down power modulation during in-situ x-ray imaging.
It is difficult to control electron doping in organic semiconductors because they often require dopants that are air-sensitive. Here, an ion-exchange doping method is introduced with improved ambient stability and crystallinity of the doped polymeric semiconductors compared to conventional methods.
Hole transporting layers between carbon electrodes and perovskite improves the performance of perovskite solar cells. Here, four interlayer materials are assessed and compared for their performance in roll-to-roll printed perovskite solar cells.
3D skyrmion strings are topological spin textures promising for spintronics applications, but their manipulation and dynamics are challenging to understand. Here, high-resolution 3D phase imaging reveals the melting dynamics of metastable skyrmions, accompanied by the emergence of (anti)hedgehogs, in (Fe,Ni,Pd)3P and FeGe helimagnets.
Poor stability against the lithium metal anode and high interfacial resistance at the cathode/solid electrolyte interface in all-solid-state batteries is an issue. Here, metal halide-doped Li7P2S8I–type solid electrolytes are demonstrated to improve electrochemical performance and stability.
Rare-earth engineering is an effective way to introduce and tune magnetism in topological materials. Here, titanium-based kagome metals RETi3Bi4 (RE = Yb, Pr, and Nd) are synthesized and characterized, whereby changing the rare earth atoms in zig-zag chains the magnetism can be tuned from nonmagnetic YbTi3Bi4 to short-range ordered PrTi3Bi4 and finally to ferromagnetic NdTi3Bi4.
Silicon spin qubits are promising for the realisation of scalable quantum computing platforms but their coherence times in natural silicon are limited by the non-zero nuclear spin of the 29Si isotope. Here, enriched 28 Si down to 2.3 ppm residual 29Si is obtained by focused ion beam implantation.
Nonlinear memory devices such as memristors, memcapacitors, and meminductors, are the building blocks of energy-efficient neuromorphic computing. Here, the authors propose a superconducting circuit design acting as a microwave quantum memcapacitor, which could be implemented in neuromorphic quantum computing architectures.
The tetragonal tungsten bronzes are promising for high-temperature energy storage applications but the mechanisms for their broad dielectric responses are unclear. Here, a comprehensive experimental and theoretical study of Sr2NaNb5O15 explains its two large dielectric anomalies in terms of structural transitions.
Ternary alloys of rare-earths and transition metals exhibit complex ferrimagnetic behavior as a function of alloy compositions. Here, X-ray magnetic circular dichroism of the Gd6(Mn1−xFex)23 series is used to explain the composition dependence of sublattice Curie temperatures in terms of element-specific magnetic moment evolution.
Magnetic Josephson junctions are important for studying the interplay between superconductivity and ferromagnetism. Here, an inverse proximity effect with tunable nanoscale spin ordering at the superconductor/ferromagnet interface of Nb-permalloy structures is observed, confirming theoretical predictions on these systems.
Due to their plasmonic properties, silver nanoparticles are promising across a vast range of applications, from physics instrumentation to biomedicine and environmental science. Here, the photon-to-heat conversion efficiency of individual nanoparticles is elucidated by designing and fabricating an ultra-sensitive bolometer with 26 pW power resolution.
Self-assembly of small nanoparticles is difficult to control and the resultant structures have weak stability. Here, a general centimeter-scale superlattice assembly strategy for noble metal nanoparticles of less than 15 nm is used to yield stable hexagonal close-packed monolayers.
Liquid marbles make use of surface particles to contain a water droplet, via a core-shell structure. Here, the fabrication of liquid marbles with a small quantity of surface polystyrene particles is demonstrated, and their rolling behavior on surfaces is studied.