Cold Plasma Jet Coupled Nanosecond Laser Ablation Scheme For Plasmonic Nanostructured Surfaces

This paper describes a study where an argon cold plasma jet, generated by a dielectric‐barrier discharge (DBD), is combined with nanosecond laser ablation (248 nm, 25 ns, 10 Hz) to deposit silver particle aerosols onto the substrate at atmospheric pressure. The deposition of the particle is examined...

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Bibliographic Details
Published in:Advanced materials interfaces 2023-07, Vol.10 (21), p.n/a
Main Authors: Khan, Taj Muhammad, Aslam, Nazim, Iqbal, Amjad, Abbasi, Shahab Ahmed, Ali, Dilawar
Format: Article
Language:English
Subjects:
Ablation
Absorption spectroscopy
Argon
argon plasma jet
Cold plasmas
computational analysis
Flow velocity
helium ion microscopy
high‐resolution transmission electron microscopy
Jet interaction
Laser ablation
Laser deposition
Lasers
Photovoltaic cells
Plasma
Plasma jets
plasmonic surfaces
Raman spectroscopy
Solar cells
Spectrum analysis
Substrates
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Summary:This paper describes a study where an argon cold plasma jet, generated by a dielectric‐barrier discharge (DBD), is combined with nanosecond laser ablation (248 nm, 25 ns, 10 Hz) to deposit silver particle aerosols onto the substrate at atmospheric pressure. The deposition of the particle is examined using various microscopy techniques and absorption spectroscopy for the plasma jet produced by operating DBD in the normal and reversed mode. Plasma facilitated the deposition process by delivering the particle to the substrate and significantly influenced its morphology depending on the jet interaction, length, and substrate position. In both cases, the particles are clustered; however, there is less deposit for the plasma ignited in the reverse mode. The theoretical analysis of the deposition process is performed using ANSYS software and evaluated in terms of plasma‐induced flow velocity. This study infers that the hybrid plasma‐laser deposition scheme considered is attractive for material processing and deposition, especially overextended substrate distances, and for altering the properties of the deposited particles for practical utilization in surface‐enhanced Raman spectroscopy, solar cells, and catalysis. Hybrid scheme of dielectric‐barrier discharge cold plasma in conjunction with laser ablation offers an effective particle deposition method at atmospheric pressure. Plasma facilitates the deposition process and altering the particle morphology and spatial distribution for direct application in surface‐enhanced Raman spectroscopy, catalysis, and solar cells.
ISSN:2196-7350
2196-7350
DOI:10.1002/admi.202300280