A.Guillermo Bracamonte et al. Editions

Scheme 1 Schematic concept of Nanostructured Non-Classical Light generation based on the control of the Nanoscale and light matter interactions towards coupling directional emissions.
This Editorial letter is about prototyping optical active Nanomaterials considering variables that modify the quantum light path.[i] The quantum level within the Nanoscale is intrinsically involved; therefore, is noted this level and beyond due to different optical active properties could be tuned. Thus, in this brief communication is intended to present topological insights controlling Nano scales, sizes, geometries and assembling for directional emission patterning. The main fact focusses on optical active materials emitting optical signalling by modification of key parameters such as electronic oscillations and electromagnetic fields through space and time control. These effects are produced from single nano architectures towards collective resonances in similar manner as waves move within confined spaces. The electronic oscillations produce electromagnetic fields with perpendicular vectorial magnetic and electrical components. This the front face of the wave advance interacting with their close surrounding. In general, the intensities of the vectorial components are proportional to sizes. However, the oscillations of electromagnetics fields with toroidal distributions form different shapes from different single nanostructured geometries. Then, when it is placed nano patterned arrays could be produced new inter-nanostructured interaction effects. In this context, when it is formed dimers, trimers, and higher assemblies towards variable micro-sized arrays is produced enhanced electromagnetic fields. These come from collective oscillations and increased vectorial components non explained just by the sum of both contributions. Thus, the Optics is modified and logically the different particles and energy modes such as quantum particles, photons, electrons and further bosonics could interact through higher intense electromagnetic fields as energy clouds that interacts and modify quantum properties. In this manner, all levels and energy modes could be modified; however the directional emission is an additional challenge where it could involve differential optical gaining media with directional enhancement within 3D (Scheme 1). Even if electromagnetics fields within could be predicted by the theory of Mie (Mie theory, or the Lorenz-Mie solution, is an exact mathematical and physical description of how electromagnetic radiation is scattered by a homogeneous spherical particle), It is no so easy to generate a model for each prototype to explain all variations applying sum or combinations of models. In majority of cases new materials are obtained and many of them are defined as metamaterials. Thus, optics is modified such as photons or electrons passing through those electromagnetic waves increasing ballistic energies and generating new quantum states. By this manner, It is produced new energy modes from these particles irradiated by different 3D electromagnetic distributions. This description of this particular situation is not the only one, at the place it is there are high number of combinations. In similar manner it is not related with linear Optics, as well could be non-linear models that describe optical behaviors. So, it is opened the design and synthesis of topological new nanoarchitectures to produce asymmetrical and directional gaining media. This proposal could be stimulated from fundamental Nanophysics and chemistry towards directional waveguiding applications.
Mie solution, is an exact mathematical and physical description of how electromagnetic radiation is scattered by a homogeneous spherical particle), It is no so easy to generate a model for each prototype to explain all variations applying sum or combinations of models. In majority of cases new materials are obtained and many of them are defined as metamaterials. Thus, optics is modified such as photons or electrons passing through those electromagnetic waves increasing ballistic energies and generating new quantum states. By this manner, It is produced new energy modes from these particles irradiated by different 3D electromagnetic distributions. This description of this particular situation is not the only one, at the place it is there are high number of combinations. In similar manner it is not related with linear Optics, as well could be non-linear models that describe optical behaviors. So, it is opened the design and synthesis of topological new nanoarchitectures to produce asymmetrical and directional gaining media. This proposal could be stimulated from fundamental Nanophysics and chemistry towards directional waveguiding applications.


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