镊子
翻译(生物学)
物理
辐射压力
拓扑(电路)
光学镊子
流离失所(心理学)
传感器
灵活性(工程)
工作(物理)
散射
领域(数学)
全息术
粒子(生态学)
开发(拓扑)
相(物质)
声学
经典力学
活性物质
计算机科学
拓扑绝缘体
网络拓扑
信号(编程语言)
声波
跟踪(教育)
作者
Laixin Huang,Xiao Xiang,Zonglin Li,Zonglin Li,Yu‐Gui Peng,Zhi-Min Li,Zhi-Min Li,Yonghao Wen,J. F. Qiu,Long-Sheng Zeng,J Chen,Fei Li,Xue-Feng Zhu,Hairong Zheng
出处
期刊:Science Advances
[American Association for the Advancement of Science]
日期:2026-01-01
卷期号:12 (1): eadz4301-eadz4301
被引量:2
标识
DOI:10.1126/sciadv.adz4301
摘要
Acoustic tweezers harness the mechanical effects of ultrasound to achieve contact-free manipulation of micro/nanoparticles. In acoustofluidics, standing-wave tweezers were widely adopted for particle trapping and translation due to their facile implementation and on-chip integrability. However, those conventional standing-wave fields, typically generated by transducer pairs, exhibit limited manipulation flexibility owing to their simplistic field configurations. Here, we demonstrate topological mass transport along arbitrarily designed trajectories by constructing localized and tunable standing-wave fields based on valley interface states. Precise phase modulation of incident waves enables efficient particle conveyance through continuous displacement of standing-wave pressure nodes or antinodes, leveraging the radiation forces from topologically protected standing waves in scattering systems. Experimental results confirm that such topological tweezing and circulating effect enables robust mass transport, showing antibackscattering characteristics and immunity against various structural defects such as sharp corners or cavities. Our work establishes a foundational paradigm for investigating the radiation forces in topological acoustic fields and advances the development of acoustofluidics technologies.
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