Researchers have developed a powerful computational framework that shows how carefully optimized nanotube shapes can amplify electromagnetic field concentration by more than 30 times compared to conventional circular nanotubes. This breakthrough opens new pathways for high-performance nanophotonic devices, sensors, and metasurfaces.

Nanotubes are widely used in nanophotonics and electromagnetic applications due to their ability to confine and manipulate electromagnetic waves at extremely small scales. Traditionally, most designs assume circular cross sections, which limits the achievable field enhancement. Until now, it has remained unclear how altering nanotube geometry could unlock stronger and more robust electromagnetic responses.

The study systematically investigated how electromagnetic waves interact with pairs of nanotubes featuring arbitrary-shaped cross sections. The research began with circular nanotube pairs to identify key structural, material, and excitation parameters that govern electric field concentration.

Building on this foundation, the team formulated a shape optimization problem aimed at maximizing the internal electric field while keeping all other operational parameters constant.

To solve this complex problem, the researchers employed an advanced numerical framework that combines:

• IsoGeometric Analysis–based Boundary Element Method (IGABEM) to accurately model electromagnetic fields around nanotube boundaries

• Hybrid optimization techniques, integrating both global and local optimizers

• Two geometric parametric models capable of generating physically valid and manufacturable nanotube cross sections

This integrated approach enabled a highly precise and efficient search for optimal nanotube geometries.

The optimized nanotube shapes demonstrated exceptional electromagnetic performance:

• Electric field concentration increased by 30 times or more compared to circular nanotube pairs

• Enhanced performance remained stable across a wide range of wave incidence angles

• Results were robust for different nanotube areas, highlighting strong design flexibility

These findings confirm that geometry alone, without changing materials or excitation conditions, can dramatically boost electromagnetic performance.

The ability to intensify electromagnetic fields at the nanoscale has major implications for:

• Nanophotonic and plasmonic devices

• High-sensitivity sensors and detectors

• Electromagnetic gratings and photonic metasurfaces

• Advanced signal processing and wave-manipulation technologies

Importantly, the developed computational method can be readily extended to finite arrays of nanotubes, enabling the rational design of collective nanostructures with tailored electromagnetic responses.

By revealing how optimal nanotube geometries drive extreme field enhancement, this work provides both practical design rules and a scalable computational toolset for next-generation electromagnetic and photonic systems. The insights gained pave the way for fine-tuned, high-efficiency metasurfaces and other advanced nanostructured technologies.