J J Liu scite author profile

J J Liu

2Publications

31Citation Statements Received

163Citation Statements Given

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Hebei Normal University

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Sub-60 °C atmospheric helium–water plasma jets: modes, electron heating and downstream reaction chemistry

Liu¹,

Kong²

2011

J. Phys. D: Appl. Phys.

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To cite this version:J J Liu, M G Kong. Sub-60°C atmospheric heliumwater plasma jets: modes, electron heating and downstream reaction chemistry. Journal of Physics D: Applied Physics, IOP Publishing, 2011, 44 (34) AbstractFor plasma treatment of many heat labile materials (e.g. living tissues) that are either moist or contain a surface layer of liquid, it is desirable that the gas plasma is generated at atmospheric pressure for process convenience and with a gas temperature ideally no more than 60 o C for mitigating permanent damage to the integrity of the test material. This implies that the liquid-containing plasma needs to be of low energy and that plasma treatment should be based largely on non-equilibrium reaction chemistry. In this contribution, a class of sub-60 o C atmospheric helium-water plasma jets is studied in terms of their main physiochemical properties. It is shown that there are five distinct modes appearing in the sequence of, with increasing voltage, the first chaotic mode, the plasma bullet mode, the second chaotic mode, the abnormal glow mode, and the nonthermal arc mode. Its chaotic modes may be sustained over a wide range of water vapour concentration (0 -2,500ppm). Compared to other liquid-containing plasmas, the He-H 2 O plasma jet operated below its nonthermal arc mode has several distinct advantages, namely very low energy consumption (2 -10 J per pulse), sub-60 o C gas temperature,

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Dynamics of Polarons in Organic Conjugated Polymers with Side Radicals

et al. 2017

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Based on the one-dimensional tight-binding Su-Schrieffer-Heeger (SSH) model, and using the molecular dynamics method, we discuss the dynamics of electron and hole polarons propagating along a polymer chain, as a function of the distance between side radicals and the magnitude of the transfer integrals between the main chain and the side radicals. We first discuss the average velocities of electron and hole polarons as a function of the distance between side radicals. It is found that the average velocities of the electron polarons remain almost unchanged, while the average velocities of hole polarons decrease significantly when the radical distance is comparable to the polaron width. Second, we have found that the average velocities of electron polarons decrease with increasing transfer integral, but the average velocities of hole polarons increase. These results may provide a theoretical basis for understanding carriers transport properties in polymers chain with side radicals.

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J J Liu

Sub-60 °C atmospheric helium–water plasma jets: modes, electron heating and downstream reaction chemistry

Dynamics of Polarons in Organic Conjugated Polymers with Side Radicals

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