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Random Laser Spectral Fingerprinting of Lithographed Microstructures
Author(s) -
Capocefalo Angela,
Quintiero Eleonora,
Bianco Monica,
Zizzari Alessandra,
Gentilini Silvia,
Conti Claudio,
Arima Valentina,
Viola Ilenia,
Ghofraniha Neda
Publication year - 2021
Publication title -
advanced materials technologies
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 2.184
H-Index - 42
ISSN - 2365-709X
DOI - 10.1002/admt.202001037
Subject(s) - optics , laser , spectral line , lithography , photonics , coherence (philosophical gambling strategy) , materials science , realization (probability) , fingerprint (computing) , scattering , emission spectrum , random laser , physics , computer science , statistics , mathematics , quantum mechanics , astronomy , lasing threshold , computer security
Coherent random lasers (RLs) originate from the resonant amplification of the light scattered by disordered media resulting in spiky emission spectra with well‐defined spectral signatures. Here coherent RL emission is proposed as a tool for identifying the spectral fingerprint of porous micro‐structured materials obtained by soft lithography techniques. The close control of the spatial patterns and structural characteristics of the scattering elements enable us to obtain stable and unique RL spectra distinctive of each lithographed device. The spectral emission has been thoroughly analyzed with respect to the morphology of the devices in terms of surface roughness and surface volume fraction, demonstrating that the packing of the scattering particles is the main factor in determining a RL emission characterized by multiple linewidths with a high level of coherence. The findings provide novel insights for the realization of miniaturized photonic devices with selectable optical features.