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Main Authors: Tassi, Camillo, Mannella, Riccardo, Tomadin, Andrea, Camposeo, Andrea, Pisignano, Dario
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2512.04811
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author Tassi, Camillo
Mannella, Riccardo
Tomadin, Andrea
Camposeo, Andrea
Pisignano, Dario
author_facet Tassi, Camillo
Mannella, Riccardo
Tomadin, Andrea
Camposeo, Andrea
Pisignano, Dario
contents Optically active networks show feature-rich emission that depends on the fine details of their geometry, and find diverse applications in random lasers, sensing devices and photonics processors. In these and other systems, a thorough and predictive characterization of how the network geometry correlates with the resulting emission spectrum would be highly important, however such outright description is still lacking. In this work, we take a step toward filling this gap, by using the well-known Steady-State ab Initio Laser Theory equations to carry out an extensive set of statistical analyses and establish connections between the random network geometry and their ultimate emission spectrum. Our results show that edge crowding (abundance of short edges in the network) is key to tune the uniformity of the modal intensity distribution of the emission spectrum. A statistical framework for the comprehensive understanding of the network statistical properties is highly significant to establish precise design rules for network-based photonic devices and intelligent systems.
format Preprint
id arxiv_https___arxiv_org_abs_2512_04811
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Statistical Insight into the Correlation of Geometry and Spectral Emission in Network Lasers
Tassi, Camillo
Mannella, Riccardo
Tomadin, Andrea
Camposeo, Andrea
Pisignano, Dario
Optics
Optically active networks show feature-rich emission that depends on the fine details of their geometry, and find diverse applications in random lasers, sensing devices and photonics processors. In these and other systems, a thorough and predictive characterization of how the network geometry correlates with the resulting emission spectrum would be highly important, however such outright description is still lacking. In this work, we take a step toward filling this gap, by using the well-known Steady-State ab Initio Laser Theory equations to carry out an extensive set of statistical analyses and establish connections between the random network geometry and their ultimate emission spectrum. Our results show that edge crowding (abundance of short edges in the network) is key to tune the uniformity of the modal intensity distribution of the emission spectrum. A statistical framework for the comprehensive understanding of the network statistical properties is highly significant to establish precise design rules for network-based photonic devices and intelligent systems.
title Statistical Insight into the Correlation of Geometry and Spectral Emission in Network Lasers
topic Optics
url https://arxiv.org/abs/2512.04811