Abstract
The interaction of electromagnetic waves with matter is at the foundation of the way we perceive and explore the world around us. In fact, when a field interacts with an object, signatures on the object’s geometry and physical properties are recorded in the resulting scattered field and are transported away from the object, where they can eventually be detected and processed. An optical field can transport information through its spectral content, its polarization state, and its spatial distribution. Generally speaking, the field’s spatial structure is typically subjected to changes under free-space propagation and any information therein encoded gets reshuffled by the propagation process. We must ascribe to this fundamental reason the fact that spectroscopy was known to the ancient civilizations already, and founded as modern science in the middle of seventeenth century, while to date we do not have an established scientific of field of ‘spatial spectroscopy’ yet. In this work we tackle this issue and we show how any field, whose evolution is dictated by Helmholtz equation, contains a universal and invariant spatial structure. When expressed in the framework of this spatial fabric, the spatial information content carried by any field reveals its invariant nature. This opens the way to novel paradigms in optical digital communications, inverse scattering, materials inspection, nanometrology and quantum optics.
Highlights
Our understanding of the many physical phenomena taking place in Nature often requires extracting information from different types of wavefields
Enough, how we are going to show in moment, it is possible to find the analytical expression for a modal decomposition, orthogonal and propagation invariant, which is compatible with Helmholtz equation
In this work we have presented the natural spatial structure of classical fields solutions of the Helmholtz equation
Summary
When a field interacts with an object, signatures on the object’s. Any further distribution of this work must maintain geometry and physical properties are recorded in the resulting scattered field and are transported away attribution to the from the object, where they can eventually be detected and processed. An optical field can transport author(s) and the title of the work, journal citation information through its spectral content, its polarization state, and its spatial distribution. When expressed in the framework of this spatial fabric, the spatial information content carried by any field reveals its invariant nature. This opens the way to novel paradigms in optical digital communications, inverse scattering, materials inspection, nanometrology and quantum optics
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