Tunable metamaterial devices have experienced explosive growth in the past decades,
driving the traditional electromagnetic (EM) devices to evolve into diversified functionalities …

Nanophotonics, manipulating light–matter interactions at the nanoscale, is an appealing
technology for diversified biochemical and physical sensing applications. Guided-wave …

Electromagnetic metamaterials are artificially engineered materials that have revolutionized
the research activities for efficient manipulation of terahertz (THz) waves in the past decade …

Metamaterials enable subwavelength tailoring of light–matter interactions, driving
fundamental discoveries which fuel novel applications in areas ranging from compressed …

In recent years, tunable metamaterials have attracted intensive research interest due to their
outstanding characteristics, which are dependent on the geometrical dimensions rather than …

In recent years, with the further ministration of the semiconductor device in integrated
circuits, power consumption and data transmission bandwidth have become insurmountable …

Metamaterials, consisting of subwavelength resonant structures, can be artificially
engineered to yield desired response to electromagnetic waves. In contrast to the naturally …

Terahertz (THz) part of the electromagnetic spectrum (0.1–10 THz) holds the key for next-
generation high-speed wireless communication, non-destructive biosensing, fingerprint …

Nanoplasmonics deals with the collective oscillation of electrons at the surface of metallic
structures at the nanometer scale. It possesses advantages including nanofocusing of …

We experimentally demonstrate the integration of a microfluidic trap array on top of
metamaterial resonators for size selective trapping and remote sensing of microparticles. A …