"If we mask part of an ordinary lens surface with an optical filter, it will increase the magnifying power of the lens. But peak field intensity drops dramatically. The same effect is typical of spherical particle-lenses in nano-scopes or high-definition optical microscopes with a magnifying power of 50 nanometers. If we use non-spherical particles, including cylinders with illuminated butt-ends, as lenses, and if we mask part of the surface, it will simultaneously boost their magnifying power and peak field intensity. This is called the amplitude mask apodization effect," Professor Igor Minin from Tomsk Polytechnic University's faculty of electronic engineering noted.
Non-spherical particles function as super-lenses accumulating evanescent (damp) waves that can form an image with unprecedentedly high definition levels.
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In their work, scientists cite experimental data confirming the existence of the amplitude mask apodization effect in the millimeter waveband. During their experiments, cuboid dielectric particles, part of whose surfaces (about 45 percent) are covered with a copper amplitude mask, showed a 36-percent increase in magnifying power, with peak field intensity levels increasing by over 30 percent.
"You could say that spherical particle-lenses boost the magnifying power of nano-scopes only through the loss of energy. But when we use non-spherical particles, the magnifying power increases at a rate commensurate with the greater peak field intensity levels," Minin added.
The results of these research projects, supported by British grants, are published in the Journal of Infrared, Millimeter and Terahertz Waves.
Tomsk Polytechnic University is involved in the Project 5-100 federal programme aiming to finance topical research projects, to ensure cost-effective cooperation between university researchers and industrial partners and to expand the research potential of Russian universities.
