As a new generation of materials/structures,heterostructure is characterized by heterogeneous zones with dramatically different mechanical,physical or chemical properties.This endows heterostructure with unique interf...As a new generation of materials/structures,heterostructure is characterized by heterogeneous zones with dramatically different mechanical,physical or chemical properties.This endows heterostructure with unique interfaces,robust architectures,and synergistic effects,making it a promising option as advanced biomaterials for the highly variable anatomy and complex functionalities of individual patients.However,the main challenges of developing heterostructure lie in the control of crystal/phase evolution and the distribution/fraction of components and structures.In recent years,additive manufacturing techniques have attracted increasing attention in developing heterostructure due to the unique flexibility in tailored structures and synthetic multimaterials.This review focuses on the additive manufacturing of heterostructure for biomedical applications.The structural features and functional mechanisms of heterostructure are summarized.The typical material systems of heterostructure,mainly including metals,polymers,ceramics,and their composites,are presented.And the resulting synergistic effects on multiple properties are also systematically discussed in terms of mechanical,biocompatible,biodegradable,antibacterial,biosensitive and magnetostrictive properties.Next,this work outlines the research progress of additive manufacturing employed in developing heterostructure from the aspects of advantages,processes,properties,and applications.This review also highlights the prospective utilization of heterostructure in biomedical fields,with particular attention to bioscaffolds,vasculatures,biosensors and biodetections.Finally,future research directions and breakthroughs of heterostructure are prospected with focus on their more prospective applications in infection prevention and drug delivery.展开更多
We report the interplay between two different topological phases in condensed matter physics,the magnetic chiral domain wall(DW),and the quantum anomalous Hall(QAH)effect.It is shown that the chiral DW driven by Dzyal...We report the interplay between two different topological phases in condensed matter physics,the magnetic chiral domain wall(DW),and the quantum anomalous Hall(QAH)effect.It is shown that the chiral DW driven by Dzyaloshinskii–Moriya interaction can divide the uniform domain into several zones where the neighboring zone possesses opposite quantized Hall conductance.The separated domain with a chiral edge state(CES)can be continuously modified by external magnetic field-induced domain expansion and thermal fluctuation,which gives rise to the reconfigurable QAH effect.More interestingly,we show that the position of CES can be tuned by spin current driven chiral DW motion.Several two-dimensional magnets with high Curie temperature and large topological band gaps are proposed for realizing these phenomena.The present work thus reveals the possibility of chiral DW controllable QAH effects.展开更多
基金The Natural Science Foundation of China(51935014,52275395,82072084)Hunan Provincial Natural Science Foundation of China(2020JJ3047)+4 种基金Central South University Innovation-Driven Research Programme(2023CXQD023)JiangXi Provincial Natural Science Foundation of China(20224ACB204013)Technology Innovation Platform Project of Shenzhen Institute of Information Technology 2020(PT2020E002)Guangdong Province Precision Manufacturing and Intelligent Production Education Integration Innovation Platform(2022CJPT019)The Project of State Key Laboratory of Precision Manufacturing for Extreme Service Performance。
文摘As a new generation of materials/structures,heterostructure is characterized by heterogeneous zones with dramatically different mechanical,physical or chemical properties.This endows heterostructure with unique interfaces,robust architectures,and synergistic effects,making it a promising option as advanced biomaterials for the highly variable anatomy and complex functionalities of individual patients.However,the main challenges of developing heterostructure lie in the control of crystal/phase evolution and the distribution/fraction of components and structures.In recent years,additive manufacturing techniques have attracted increasing attention in developing heterostructure due to the unique flexibility in tailored structures and synthetic multimaterials.This review focuses on the additive manufacturing of heterostructure for biomedical applications.The structural features and functional mechanisms of heterostructure are summarized.The typical material systems of heterostructure,mainly including metals,polymers,ceramics,and their composites,are presented.And the resulting synergistic effects on multiple properties are also systematically discussed in terms of mechanical,biocompatible,biodegradable,antibacterial,biosensitive and magnetostrictive properties.Next,this work outlines the research progress of additive manufacturing employed in developing heterostructure from the aspects of advantages,processes,properties,and applications.This review also highlights the prospective utilization of heterostructure in biomedical fields,with particular attention to bioscaffolds,vasculatures,biosensors and biodetections.Finally,future research directions and breakthroughs of heterostructure are prospected with focus on their more prospective applications in infection prevention and drug delivery.
基金the National Natural Science Foundation of China(Grant Nos.11874059 and 12174405)the Key Research Program of Frontier Sciences,CAS(Grant No.ZDBS-LY-7021)+3 种基金the Ningbo Key Scientific and Technological Project(Grant No.2021000215)“Pioneer”and“Leading Goose”R&D Program of Zhejiang Province(Grant No.2022C01053)Zhejiang Provincial Natural Science Foundation(Grant No.LR19A040002)Beijing National Laboratory for Condensed Matter Physics(Grant No.2021000123)。
文摘We report the interplay between two different topological phases in condensed matter physics,the magnetic chiral domain wall(DW),and the quantum anomalous Hall(QAH)effect.It is shown that the chiral DW driven by Dzyaloshinskii–Moriya interaction can divide the uniform domain into several zones where the neighboring zone possesses opposite quantized Hall conductance.The separated domain with a chiral edge state(CES)can be continuously modified by external magnetic field-induced domain expansion and thermal fluctuation,which gives rise to the reconfigurable QAH effect.More interestingly,we show that the position of CES can be tuned by spin current driven chiral DW motion.Several two-dimensional magnets with high Curie temperature and large topological band gaps are proposed for realizing these phenomena.The present work thus reveals the possibility of chiral DW controllable QAH effects.