Future technologies underpinning multifunctional physical and chemical systems and
compact biological sensors will rely on densely packed transformative and tunable circuitry …

The rapid developments in nanotechnology and plasmonics allow the manipulation of light
at nanometer scales, such as light propagation and resonances. Differing from the …

Fano resonance arising from the interaction between a broad “bright” mode and a narrow
“dark” mode has been widely investigated in symmetry-breaking structures made of noble …

Plasmon-induced magnetic resonance has shown great potentials in optical metamaterials,
chemical (bio)-sensing, and surface-enhanced spectroscopies. Here, we have theoretically …

Metallic nanostructures can be used to manipulate light on the subwavelength scale to
create tailored optical material properties. Next to electric responses, artificial optical …

Electromagnetically induced transparency is a type of quantum interference that induces
near-zero reflection and near-perfect transmission. As a classical analogy, metal …

The possibility of achieving optical magnetism at visible frequencies using plasmonic
nanostructures has recently been a subject of great interest. The concept is based on …

High-index dielectric nanostructures support inherently strong magnetic dipole (MD)
resonances at optical frequencies with minimal dissipative absorptions. They are promising …

Dielectric nanoparticles with both strong electric and magnetic dipole (ED and MD)
resonances offer unique opportunities for efficient manipulation of light-matter interactions …

The magnetic response of most natural materials, characterized by magnetic permeability, is
generally weak. Particularly, in the optical range, the weakness of magnetic effects is directly …