Understanding light interaction with metallic structures provides opportunities of
manipulation of light, and is at the core of various research areas including terahertz (THz) …

Subwavelength electromagnetic field localization has been central to photonic research in
the last decade, allowing us to enhance sensing capabilities as well as increase the …

Stroboscopic visualization of nuclear or electron dynamics in atoms, molecules or solids
requires ultrafast pump and probe pulses and a close to perfect synchronization between …

Terahertz (THz) radiation promises breakthrough advances in compact advanced
accelerators due to the gigavolts-per-meter fields achievable, but the challenge of …

Cavity control of quantum matter may offer new ways to study and manipulate many-body
systems. A particularly appealing idea is to use cavities to enhance superconductivity …

Through the manipulation of metallic structures, light–matter interaction can enter into the
realm of quantum mechanics. For example, intense terahertz pulses illuminating a metallic …

Three-dimensional printing based on fused deposition modeling has been shown to provide
a cost-efficient and time-saving tool for fabricating a variety of THz optics for a frequency …

Quantum tunneling in plasmonic nanostructures has presented an interesting aspect of
incorporating quantum mechanics into classical optics. However, the study has been limited …

The full exploitation of advanced light sources in the terahertz (THz) frequency range
requires versatile experimental tools to fully characterize the spatial, temporal, and spectral …

Terahertz (THz) nanogap structures have emerged as versatile platforms for THz science
and applications by virtue of their strong in-gap field enhancements and accompanying high …