1 nm‐Resolution Sorting of Sub‐10 nm Nanoparticles Using a Dielectric Metasurface with Toroidal Responses
Hong Luo,
Xiang Fang,
Chengfeng Li,
Xinhua Dai,
Ning Ru,
Minmin You,
Tao He,
Pin Chieh Wu,
Zhanshan Wang,
Yuzhi Shi,
Xinbin Cheng
Affiliations
Hong Luo
Institute of Precision Optical Engineering School of Physics Science and Engineering Tongji University Shanghai 200092 China
Xiang Fang
Technology Innovation Center of Mass Spectrometry for State Market Regulation Center for Advanced Measurement Science National Institute of Metrology Beijing 100029 China
Chengfeng Li
Institute of Precision Optical Engineering School of Physics Science and Engineering Tongji University Shanghai 200092 China
Xinhua Dai
Technology Innovation Center of Mass Spectrometry for State Market Regulation Center for Advanced Measurement Science National Institute of Metrology Beijing 100029 China
Ning Ru
Technology Innovation Center of Mass Spectrometry for State Market Regulation Center for Advanced Measurement Science National Institute of Metrology Beijing 100029 China
Minmin You
National Key Laboratory of Advanced Micro and Nano Manufacture Technology Shanghai Jiao Tong University Shanghai 200240 China
Tao He
Institute of Precision Optical Engineering School of Physics Science and Engineering Tongji University Shanghai 200092 China
Pin Chieh Wu
Department of Photonics National Cheng Kung University Tainan 70101 Taiwan
Zhanshan Wang
Institute of Precision Optical Engineering School of Physics Science and Engineering Tongji University Shanghai 200092 China
Yuzhi Shi
Institute of Precision Optical Engineering School of Physics Science and Engineering Tongji University Shanghai 200092 China
Xinbin Cheng
Institute of Precision Optical Engineering School of Physics Science and Engineering Tongji University Shanghai 200092 China
Sorting nanoparticles is of paramount importance in numerous physical, chemical, and biomedical applications. Current technologies for sorting dielectric nanoparticles have a common size limit and resolution approximately of 20 and 10 nm, respectively. It remains a grand challenge to push the limit. Herein, the new physics that deploys toroidal and multipole responses in a dielectric metasurface to exert strong and distinguishable optical forces on sub‐10 nm nanoparticles is unravelled. The electric toroidal dipole, electric dipole, and quadrupole emerge with distinct light and force patterns, which can be leveraged to promise unprecedented high‐precision manipulations, such as sorting sub‐10 nm polystyrene nanoparticles at 1 nm resolution, sorting 20 nm proteins/exsomes at 3 nm resolution, conveying, and concentrating 100 nm gold nanoparticles. Remarkably, the design can also be employed to screen out medium‐sized nanoparticles from a mixture of nanoparticles with over three sizes. This optofluidic manipulation platform opens the new way to explore intriguing optical modes for the powerful manipulation of nanoparticles with nanometer precisions and low laser powers.
