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The structure of a commercially important glass-ceramic ZrO₂-doped lithium aluminosilicate system during its initial nucleation stage was investigated by an X-ray multiscale analysis which enables us to observe the structure from the atomic to the nanometer scale by using diffraction, small-angle scattering, absorption, and anomalous scattering techniques. The combinatorial approach revealed that the formation of edge sharing between the ZrO_x polyhedra and (Si/Al)O₄ tetrahedra, and that the Zr-centric periodic structure in which the local structure of the Zr⁴⁺ ions resembled a cubic or tetragonal ZrO₂ crystalline phase was potentially the initial crystal nucleus for the Zr-doped lithium aluminosilicate glass-ceramic.

Schematic diagrams of GORoM adhesive and osteoporotic fractures treatment. A The process of OVX rat model establishment and GORoM adhesive implantation. B Osteoporotic fracture healing was mediated by the osteogenesis promotion and osteoclast inhibition.

We demonstrate the magnetic-field induced reversal of antiferromagnetic spins and the electric field modulation of the switching field. The modulation efficiency is significantly high, greater than 4 T nm/V, and this giant modulation efficiency is attributed to the magnetoelectric effect of the antiferromagnetic Cr₂O₃. The magnetoelectric (ME) based mechanism provides a scheme for the energy-efficient, nonvolatile, deterministic 180° switching of the magnetic state in the pure antiferromagnetic (AFM) component. This study represents a great advancement in the AFM-based ME random access memory with ultralow writing power, an inherently fast switching speed and superior robustness to the magnetic state.

This research is emphasized particularly on cathodes (such as carbon, metal oxides, MXenes, and redox-active polymers), anodes (such as Zn-based composite materials and Zn-free materials), electrolytes (organic/ionic liquid electrolytes, WiSs, redox electrolytes, polymer or solid electrolytes) as well as the design of a novel device for ZHSCs.

Bayesian optimization improved the thermoelectric properties of InGaAsSb thin films; this domain warrants comprehensive investigation due to the need to simultaneously control multiple parameters, such as, the composition, dopant concentration, and film-deposition temperatures. After six optimization cycles, the dimensionless figure of merit exhibited an approximately threefold improvement compared to its values obtained in the random initial experimental trials. These findings not only promote the development of thermoelectric devices based on III–V semiconductors but also highlight the effectiveness of using Bayesian optimization for multicomponent materials.

The energy loss mechanism due to magnetostriction was clarified by analytical formulation considering the viscosity of magnetic materials. Effects of magnetostriction have been focused on contributions to magnetic anisotropy. However, our formulation shows that the magnetic anisotropy due to magnetostriction cannot explain excess losses in nanocrystalline soft magnetic materials, and the viscosity causes resistance forces acting on domain wall motions. This viscous resistance dissipates the magnetic energy and generates the energy loss, which has the same frequency dependence as anomalous eddy current loss. The results of this research provide new design criteria for ultra-efficient soft magnetic materials.

A novel magnetic anisotropic hydrogel (MAH) with magnetic and topographic anisotropy was designed by combining static magnetic field-induced magnetic nanomaterials and a hydrogel. The duel anisotropic hydrogel promotes osteogenic differentiation of BMSCs through upregulating SNHG5 and downstream SIRT6, which modulated the level of NOTCH1/2 by antagonizing DNMT1 protein stability.

Despite years of exploration, numerous challenges remain unresolved in the field of hydrogels and hydrogel membranes for bone repair. In this review, we provide a comprehensive overview of the fundamental principles and current development status of hydrogel materials for bone repair, including their mechanisms, formation principles, and medical benefits in bone regeneration. Additionally, we summarize recent effective strategies to develop advanced hydrogels and technical approaches for bone repair while also discussing future directions.

The figure depicts a new type of transparent electrode recording array made of vertically aligned zinc oxide nanotubes grown on graphene (top middle). The nanotubes are formed by sharp nanowalls to penetrate the cell (top left) while transparent graphene layers allow imaging the neurons using with conventional microscopy (top right). As a result, simultaneous recording of electrical signals was obtained from multiple neurons at single-cell resolution. Moreover, the signals had distinguishable waveforms that implicated extracellular- and intracellular-like electrophysiological voltage changes (bottom).

A biodegradable triboelectric nanogenerator made from both natural and synthetic biodegradable materials that is utilized to collect mechanical energy in vivo and transduce it into electricity. Reed film and polylactic acid were chosen among different biodegradable materials as the triboelectric layers due to having the best output performance. The nanogenerator was connected to an interdigital electrode to generate an electric field, which stimulated the accelerated release of doxorubicin from red blood cells in targeted drug delivery systems. The release of doxorubicin normalized, facilitating the precise killing of cancer cells, demonstrating the broad potential in the field of cancer treatments.

Cryomicroneedles (cryoMNs) permit the precise delivery of therapeutic cells into the skin, but are limited by the cold-chain transportation and storage. This article introduces an innovative solution to use a prefabricated porous microneedle scaffold that can be shipped at room temperature and allow on-site cell loading and usage in the clinic (i.e., the second generation cryoMNs or S-cryoMNs). The study investigates the loading and intradermal delivery of three cell types in clinically relevant in vitro and in vivo models, including mesenchymal stem cells for wound healing, melanocytes for vitiligo treatment, and antigen-pulsed dendritic cells for cancer vaccination.

Topological transition of a bubble to a skyrmion by the controlled magnetic monopoles injection in Fe/Gd magnetic multilayers. The magnetic monopoles injected from the top and bottom surfaces are topologically characterized by Q = −1 and Q = +1, respectively.

In this paper, we report the dimensional control of the interface coupling-induced ferromagnetic phase in perovskite-CaRuO₃/infinite-layered-SrCuO₂ superlattices. The Hall and magnetoresistance measurements indicate the appearance of an interfacial ferromagnetic state in the originally paramagnetic CaRuO₃ layers when the CaRuO₃ layer is in proximity to the chain-type SrCuO₂ layers; this superlattice has the highest Curie temperature of ~75 K and perpendicular magnetic anisotropy. Along with the thickness-driven structural transition from chain-type to planar-type of the SrCuO₂ layers, the interfacial ferromagnetic order gradually deteriorates and finally disappears.

Wearable devices provide an alternative way to clinically diagnose respiratory diseases in a non-invasive and real-time manner. In this review, we summarize the recent developments in the field of wearable respiratory sensors, including the methods to synthesize various sensing materials, the ways to improve respiratory sensing performances, and the feature comparison among different sensing materials. We also summarize the concentrations, sources and associated diseases of various biomarkers in exhaled gas. Finally, we discuss current trends in the field to provide predictions for the future trajectory of wearable respiratory sensors.

The lymphatic system is essential for maintaining homeostasis of our body. Understanding the impact of environmental factors on the lymphatic system and regulating its condition are therefore crucial. We developed a microfluidic device culturing functional skin barrier and lymphatic vessel monolayer. A deep-learning algorithm was employed to validate the pro-lymphangiogenic character of a natural substance Lymphanax™, an extract of Panax Ginseng root. We foresee this platform functioning as a valuable research tool for the pharmaceutical and cosmetic industries, replacing the need for animal models.

We investigate the anomalous transverse conductivities of a two-dimensional (2D) magnetic Fe₃GaTe₂ system (monolayer to four-layer thickness). A giant anomalous thermal Hall conductivity (ATHC) of -0.14 W/K.m is obtained in the four-layer structure, and this value is comparable to the typical ATHC found in bulk materials which is rare to find in low-dimensional systems. Our findings suggest that the ultra-thin 2D Fe₃GaTe₂ system could be a promising platform for future spintronics and spin caloritronics device applications.

The ultrabroadband absorptive refractory plasmonics is demonstrated with TiN and TiO₂ deposited onto an anodized aluminum oxide template. The absorber shows ultrabroadband absorption in the solar spectrum (400–2500 nm). Furthermore, the absorber shows an extended hot carrier lifetime and improved efficiency of photocatalytic hydrogen production. This novel ultrabroadband absorber has great potential to provide a sustainable and cost-effective route for hydrogen generation from solar energy.

Biomaterial fabrication techniques and therapeutic strategies for spinal cord injury. This review focuses on the most recent advancements of biomaterial-based therapeutics for the treatment of spinal cord injury. The outer ring of the figure shows four fabrication techniques for tissue engineering: hydrogel, electrospinning, 3D printing and decellularization. The inner ring shows the injured spinal cord and the roles of biomaterials in spinal cord injury repair, for instance, restoring the blood‒spinal cord barrier (BSCB).

Magnonic noise has unveiled magnon dynamics, including nonlinear scattering processes.