Wavelength-scale lasers provide promising applications through low power consumption
requiring for optical cavities with increased quality factors. Cavity radiative losses can be …

The establishment of non-Hermitian quantum mechanics (such as parity–time (PT)
symmetry) stimulates a paradigmatic shift for studying symmetries of complex potentials …

Graphene is a 2D honeycomb lattice consisting of a single layer of carbon atoms. Graphene
has become one of the most preferred materials for sensor development due to its …

Nanolasers are key elements in the implementation of optical integrated circuits owing to
their low lasing thresholds, high energy efficiencies, and high modulation speeds. With the …

High quality factor (Q‐factor) resonance can effectively enhance light–matter interactions,
but suffers from radiative losses caused by fabrication imperfections and material impurities …

Low‐dimensional materials (LDMs) provide an unprecedented avenue having the potential
to disruptively revolutionize the information and communication technologies. The rise of …

Graphene nanostructures with complex geometries have been widely explored for
plasmonic applications, as their plasmonic resonances exhibit high spatial confinement and …

Stable electrical modulation of plasmonic nanolasers is achieved on a hybrid graphene–
insulator–metal (GIM) platform at room temperature. To support surface plasmon polariton …

Borazino-doped nanographenes belong to a special class of flat heteroaromatic networks
comprising one or more fully formed borazino (B3N3) units in their framework. These …

We propose surface plasmon resonance biosensors based on crumpled graphene and
molybdenum disulphide (MoS_2) flakes supported on stretchable polydimethylsiloxane …