Ashkan Rezanejad, Mostafa Mousa, Christian D. Lorenz, Matthew Howard, Antonio Elia Forte
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引用次数: 0
摘要
颗粒力学超材料研究论文(10.1002/adfm)。202516484), Antonio Elia Forte及其同事介绍了纠缠颗粒超材料-几何上复杂的颗粒簇,其互锁驱动突现的可调特性。他们确定了导致纠缠的几何特征,通过解纠缠动力学量化其强度,并通过改变颗粒形状和数量来编程联锁。由电磁铁控制的铁磁颗粒与非铁磁目标纠缠(见封面),实现鲁棒的集体拾取和选择性检索,为物质操纵中的可编程纠缠奠定了基础。
Programmable Entanglement of Granular Mechanical Metamaterials (Adv. Funct. Mater. 41/2025)
Granular Mechanical Metamaterials
In their Research Article (10.1002/adfm.202516484), Antonio Elia Forte and co-workers introduce entangled granular metamaterials—clusters of geometrically complex grains whose interlocking drives emergent, tunable properties. They identify the geometric features that enable entanglement, quantify its strength via disentanglement dynamics, and program interlocking by varying grain shape and number. Ferromagnetic grains controlled by an electromagnet entangle with non-ferromagnetic targets (shown in the cover) to achieve robust collective picking and selective retrieval, establishing a foundation for programmable entanglement in matter manipulation.
期刊介绍:
Firmly established as a top-tier materials science journal, Advanced Functional Materials reports breakthrough research in all aspects of materials science, including nanotechnology, chemistry, physics, and biology every week.
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