Field manipulation of electromagnetically induced transparency analogue in terahertz metamaterials for enhancing liquid sensing

Terahertz (THz) metamaterial sensing, an emerging technology in biomedical sciences, has made considerable progress with unique characteristics, such as label-free, non-invasive, non-destructive, and efficient. However, excellent sensing performance involves the need for extremely strong light-matter interaction that is difficult to implement for the intrinsic divergent electric field excited on the surface of metamaterials. Here, an innovative method of manipulating the electric field to realize maximumly light-matter interaction for enhancing liquid sensing at THz frequencies is reported. The electric field of electromagnetically induced transparency (EIT) resonance is tightly confined inside the structure around the quasi-dark mode by optimizing the fully-enclosed metamaterial structure design. More importantly, the electric field is enhanced and the part that permeates into the substrate is exploited, together with the formation of inartificial fluid loading units by the effective regional substrate etching, exhibiting the enhanced interaction between the polar liquids and the THz waves. The measurements reveal a significantly improve in sensitivity of 0.312 THz/RIU, which is 9.8 times that without etching by contrast. The strong light-matter interaction implements in THz metamaterial via the electric field manipulation holds bright promises for realizing highly sensitive THz sensing, forging a route for real-time supervising trace biomolecules.

Automated summary

THz metamaterial sensing is an emerging technology in biomedical sciences with unique characteristics. This study reports an innovative method of manipulating the electric field to enhance liquid sensing at THz frequencies, which holds bright promises for real-time monitoring of trace biomolecules.