Metamaterial-based sensors, working in the GHz to THz range, allow for highly sensitive, label-free detection of biological samples.
A rational method for organizing nanomaterials into functional layered structures, often utilizing layer-by-layer assembly.
Techniques like electron-beam lithography, photolithography, and advanced 3D manufacturing allow for the creation of intricate, periodic, or quasi-periodic nanostructure arrays.
Metamaterial-based sensors, working in the GHz to THz range, allow for highly sensitive, label-free detection of biological samples.
A rational method for organizing nanomaterials into functional layered structures, often utilizing layer-by-layer assembly. Functional Nanostructures and Metamaterials for...
Techniques like electron-beam lithography, photolithography, and advanced 3D manufacturing allow for the creation of intricate, periodic, or quasi-periodic nanostructure arrays. Metamaterial-based sensors, working in the GHz to THz