Magneto-optics (MO) is an effervescent research field, with a wide range of potential
industrial applications including sensing, theranostics, pharmaceutics, magnetometry, and …

Electromagnetic anapole mode is a nonradiative state of light originating from the
deconstructive interference of radiation of the oscillating electric and toroidal dipole …

Light carries energy and momentum, laying the physical foundation of optical manipulation
that has facilitated advances in myriad scientific disciplines, ranging from biochemistry and …

Optical tweezers have had a major impact on bioscience research by enabling the study of
biological particles with high accuracy. The focus so far has been on trapping individual …

This study addresses the challenge of trapping nanoscale biological particles using optical
tweezers without the photothermal heating effect and the limitation presented by the …

Anapole states associated with the destructive interference between dipole and toroidal
moments result in suppressed scattering accompanied by strongly enhanced near fields. In …

In this paper, we have proposed a graphene-based tunable plasmonic sensor in the far-
infrared region. Our structure consists of patterned graphene disks on a SiO 2 gap dielectric …

The light manipulation beyond the diffraction limit plays an invaluable role in modern
physics and nanophotonics. In this work, we have demonstrated a strong coupling with a …

Exosomes (EXOs) play a crucial role in biological action mechanisms. Understanding the
biological process of single-molecule interactions on the surface of the EXO membrane is …

Anapole modes supported by well-designed dielectric nanostructures have attracted
extensive attention in the field of nanophotonic applications owing to their unique strong …