_ Department of nanoelectronics and (plasmonic waves)
Optimizing the architecture of multi-element nano-optical circuits and introducing some traditional technologies using optical behavior
Researcher and author: Dr. ( Afshin Rashid)
Note: Architecture optimization of traditional multi-element and multi-technology optical circuits is possible by using the unique optical behavior of nano-optics, integrated "self-integration" can be achieved by layering one on the other to create overall optical effects. brought
Spatial integration can be achieved by organizing different optical functions into an array structure through repeating nanopatterns. Composite integration is achieved by adding a nano-optical layer(s) to functional optical materials.
Through the appropriate combination of materials and structures, nano-optical devices can perform any passive optical function, including polarization filtering, phase retardation, spectral filtering, and emission management (e.g., lenses and beam splitters). Various functions can be designed for free space and wave based applications. Nano-optical devices can also be designed to operate in any wavelength range. The original method can be used for UV, visible and IR wavelengths with suitable modifications in dimensions and structural materials. In addition, they can form the core of an optical system. Practical applications of nano-optics require a complete optical system consisting of nano-patterned materials and adjacent materials including optical substrates and thin film coatings. Optical nanostructures are defined as a combination of material and physical properties.
Conclusion :
Architecture optimization of traditional multi-element and multi-technological optical circuits is possible using the unique optical behavior of nano-optics. A seamless "self-integration" can be achieved by layering one over the other to create overall optical effects.
Researcher and author: Dr. ( Afshin Rashid)
Specialized doctorate in nano-microelectronics