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Random Lasing via Plasmon-Induced Cavitation of Microbubbles

Rodrigo Sato, Joel Henzie, Boyi Zhang, Satoshi Ishii, Shunsuke Murai, Ken Takazawa, Yoshihiko Takeda

2021Nano Letters17 citationsDOI

Abstract

Numerous laboratories have observed random lasing from optically pumped solutions of plasmonic nanoparticles (NPs) suspended with organic dye molecules. The underlying mechanism is typically attributed to the formation of closed-loop optical cavities enabled by the large local field and scattering enhancements in the vicinity of plasmonic NPs. In this manuscript, we propose an alternative mechanism that does not directly require the plasmon resonance. We used high-speed confocal microspectroscopy to observe the photophysical dynamics of NPs in solution. Laser pulses induce the formation of microbubbles that surround and encapsulate the NPs, then sharp peaks <1.0 nm are observed that match the spectral signature of random lasing. Electromagnetic simulations indicate that ensembles of microbubbles may form optical corral containing standing wave patterns that are sufficient to sustain coherent optical feedback in a gain medium. Collectively, these results show that ensembles of plasmonic-induced bubbles can generate optical feedback and random lasing.

Topics & Concepts

Lasing thresholdPlasmonMaterials sciencePlasmonic nanoparticlesRaman scatteringMicrobubblesOptical tweezersRandom laserSurface plasmon resonanceScatteringLaserOptoelectronicsPhotothermal therapyNanoparticleOpticsNanotechnologyRaman spectroscopyPhysicsWavelengthUltrasoundAcousticsRandom lasers and scattering mediaOrbital Angular Momentum in OpticsGold and Silver Nanoparticles Synthesis and Applications
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