Low-temperature argon plasma jet with cascading electrode technique for biological applications

Seyfi, Pourya; Keshavarzi, Maryam; Zahedi, Saeed; Khademi, Ahmad; Ghomi, Hamid

doi:10.1038/s41598-022-21664-9

Cited by 5 publications

(2 citation statements)

References 36 publications

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“…In experimental results suggesting that an unusual spectral change has an important effect on the change in liquid flows, the emission spectra were dominated by excited OH (309 nm), excited molecular N 2 (315-380 nm, 2nd positive system), and excited atomic Ar (around 420 nm, 700-840 nm). [27][28][29][30][31][32] As the frequency increased from 4 to 10 kHz, the emission intensities of excited OH and excited molecular N 2 decreased while those of excited atomic Ar increased. Therefore, the plasma-driven liquid flows can be controlled by adjusting the active species supplied to the liquid surface.…”

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confidence: 99%

“…Figures 5(a) and 5(b) show the emission spectra in the 300-440 nm (exposure time = 1000 ms) and the 700-840 nm (exposure time = 20 ms) wavelength ranges, respectively.The emission spectra were minor in the 440-700 nm wavelength range. In experimental results suggesting that an unusual spectral change has an important effect on the change in liquid flows, the emission spectra were dominated by excited OH (309 nm), excited molecular N 2 (315-380 nm, 2nd positive system), and excited atomic Ar (around 420 nm, 700-840 nm) [27][28][29][30][31][32]. As the frequency increased from 4 to 10 kHz, the emission intensities of excited OH and excited molecular N 2 decreased while those of excited atomic Ar increased.…”

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confidence: 99%

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Instant switching control between two types of plasma-driven liquid flows

Kawasaki

Shen

Shi

et al. 2023

Jpn. J. Appl. Phys.

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Plasma-driven liquid flows that are generated in bulk liquid by plasma irradiation are one of the key factors in understanding the interaction between plasma and liquid. In this work, the direction of the plasma-driven liquid flow was successfully switched and controlled only by changing the frequency of argon plasma jet generation. The liquid flow could switch in the opposite direction within 3 s after the frequency change. Changes in the emission spectra with frequency have an important effect on the liquid flows, with results from current waveforms indicating that the frequency also changes the characteristics of the plasma jet.

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confidence: 99%

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confidence: 99%

Instant switching control between two types of plasma-driven liquid flows

Kawasaki

Shen

Shi

et al. 2023

Jpn. J. Appl. Phys.

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Novel self-assembled graphene oxide coating by atmospheric pressure plasma jet

Cabello Mendez,

Pérez Bueno,

Meas Vong

et al. 2024

Materials Science in Semiconductor Processing

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A large-scale cold plasma jet: generation mechanism and application effect

CUI 崔,

ZHANG 张

2024

Plasma Sci. Technol.

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Atmospheric pressure cold plasma jets (APCPJs) typically exhibit a slender, conical structure, which imposes limitations on their application for surface modification due to the restricted treatment area. In this paper, we introduce a novel plasma jet morphology known as the large-scale cold plasma jet (LSCPJ), characterized by the presence of both a central conical plasma jet and a peripheral trumpet-like diffuse plasma jet. The experimental investigations have identified the factors influencing the conical and the trumpet-like diffuse plasma jet, and theoretical simulations have shed light on the role of the flow field and the electric field in shaping the formation of the LSCPJ. It is proved that, under conditions of elevated helium concentration, the distributions of impurity gas particles and the electric field jointly determine the plasma jet's morphology. High-speed ICCD camera images confirm the dynamic behavior of plasma bullets in LSCPJ, which is consistent with the theoretical analysis. Finally, it is demonstrated that when applied to the surface treatment of silicone rubber, LSCPJ can achieve a treatment area over 28 times larger than that of APCPJ under equivalent conditions. This paper uncovers the crucial role of impurity gases and electric fields in shaping plasma jet morphology and opens up the possibility of efficiently diversifying plasma jet generation effects through external electromagnetic fields. These insights hold the promise of reducing the generation cost of plasma jets and expanding their applications across various industrial sectors.

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Low-temperature argon plasma jet with cascading electrode technique for biological applications

Cited by 5 publications

References 36 publications

Instant switching control between two types of plasma-driven liquid flows

Instant switching control between two types of plasma-driven liquid flows

Novel self-assembled graphene oxide coating by atmospheric pressure plasma jet

A large-scale cold plasma jet: generation mechanism and application effect

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