About the work
Resumen
Visible photonic systems can be described in a compact and physically meaningful way through global reactivity
descriptors. In this work, we use a simple algebraic framework based on ionization potential, electron affinity, energy
gap, hardness, softness, chemical potential, electrophilicity, and an adaptability index. The aim is to replace advanced
calculus with elementary chemical-physical descriptors while preserving the interpretation of stability, sensitivity, and
reconfiguration. The resulting framework is particularly useful for analyzing how a structured photonic medium can
support readable state evolution, adaptive response, and dynamic visualization. By focusing on algebraic descriptors
rather than differential or integral formalisms, the present approach offers a more direct and transparent route to the
interpretation of photonic reactivity and functional organization.
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Title Visible Photonics for Structured Computation and Dynamic Visualization
Resumen
Visible photonic systems can be described in a compact and physically meaningful way through global reactivity
descriptors. In this work, we use a simple algebraic framework based on ionization potential, electron affinity, energy
gap, hardness, softness, chemical potential, electrophilicity, and an adaptability index. The aim is to replace advanced
calculus with elementary chemical-physical descriptors while preserving the interpretation of stability, sensitivity, and
reconfiguration. The resulting framework is particularly useful for analyzing how a structured photonic medium can
support readable state evolution, adaptive response, and dynamic visualization. By focusing on algebraic descriptors
rather than differential or integral formalisms, the present approach offers a more direct and transparent route to the
interpretation of photonic reactivity and functional organization.
Work type Technical
Tags electronic rigidity, dmft, condensed matter physics, quasiparticles, metal-insulator transition, electronic correlations, scaling law, electronic transport, conductivity, band gap, hubbard model
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Registry info in Safe Creative
Identifier 2605315836979
Entry date May 31, 2026, 7:11 PM UTC
License Creative Commons Attribution 4.0
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Copyright registered declarations
Author. Holder David Escobar Martin. Date May 31, 2026.
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