Researchers Employ Antennas for Angstrom Displacement Sensing

Release time:2020-06-24Browse times:48

Micro - nano Optics and Technology Research Group led by Prof. LU Yonghua and Prof. WANG Pei from University of Science and Technology of China of the Chinese Academy of Sciences (CAS) realized nanometric displacement measurement through the interaction between the illumination optical field and the optical antennas. This study was published on Physical Review Letters.

Optical metrology is of particular significance for it allows measurements of distance or displacement in a noncontact high-precision way. However, despite of the wide application in longitudinal displacement measurement of interferometric method, such as laser radar, laser ranging and small vibration measurement, lateral displacement perpendicular to the direction of the beam are hard to detect through conventional methods.

The researchers presented a novel technique based on directional excitation of surface plasmon polaritons (SPPs). 

They first excited asymmetric SPPs with a pair of optical slot antennas under the illumination of the focused Hermite-Gaussion (HG) (1,0) mode light. Then, by detecting the SPPs leakage at the back-focal plane of an oil-immersed objective, theysensitively measured the transverse displacement. 

Unlike the previous strategy to retrieve the free scattering signals, which remains challenging even when employing a weak measurement technique, the SPPs leakage pattern is spatially separated from the forward scattering of the slot antennas, and thus could be utilized to monitor displacements in the back-focal plane

Schema of the near-field interaction between the antennas and incident light field. (Image by ZANG Tianyang et al.)

The resolution of their system reaches subwavelength level (~0.3 nm). However, the extreme resolution could be down to angstrom level. It is potentially applicable in superresolution microscopy, semiconductor lithography, and calibration of nanodevices. 

Paper link: 

https://journals.aps.org/prl/abstract/10.1103/PhysRevLett.124.243901

(Written by JIANG Pengcen, USTC News Center)