Reactive Species Production In Argon And Helium Plasma Jets: Reactivity Transfer From Plasma To Liquid Layers

Q1 Medicine

Clinical Plasma Medicine Pub Date : 2018-02-01 DOI:10.1016/j.cpme.2017.12.052

Natalia Babaeva *, George Naidis

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引用次数: 2

Abstract

Atmospheric pressure plasma jets are often used in plasma medicine as sources of reactive species in biomedical applications including the treatment of wounds and cancerous tumors. A rare gas or a mixture of a rare gas with a small percentage of oxygen are often used as a plasma-forming gases [1]. The biological responses are attributed to the production of reactive oxygen and nitrogen species. The reactive species generated by the plasma diffuse through a thin layer of a biological liquid which usually covers the treated sample.

In this work, we discuss results from computational investigations of properties of a single jet and jets array operated in He and Ar. We quantify densities and fluxes of reactive species produced by jets in the bulk plasma (Figure 1). We then investigate the reactivity transfer from the plasma into the liquid. As this process typically occurs on a large dynamic ranges of timescales, the plasma–liquid interactions and liquid phase chemistry are considered on a short (ns) and long (ms) time scales.

This investigation is conducted using the 2D modeling platform nonPDPSIM, which solves transport equations for charged and neutral species, Poisson’s equation for the electric potential, the electron energy conservation equation for the electron temperature and Navier–Stokes equations for the neutral gas flow. The model is essentially the same as used in [2]. The reaction mechanism includes plasma and neutral chemistry for He/humid air and Ar/humid air as well as liquid phase chemistry.

Download : Download high-res image (388KB)
Download : Download full-size image

Figure 1. (a) and (c): Flow patterns for helium and argon jet into ambient air. Numbers at the lines show helium and argon mole fraction. (b) and (d): OH radicals production during a short plasma time scale for helium and argon jet, respectively.

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氩和氦等离子体射流中反应物质的产生:从等离子体到液体层的反应性转移

常压等离子体射流常用于等离子体医学，作为生物医学应用中反应物质的来源，包括伤口和癌性肿瘤的治疗。稀有气体或稀有气体与少量氧的混合物常被用作形成等离子体的气体[1]。生物反应归因于活性氧和活性氮的产生。等离子体产生的反应物质通过通常覆盖被处理样品的生物液体的薄层扩散。在这项工作中，我们讨论了在He和Ar中运行的单个射流和射流阵列特性的计算研究结果。我们量化了大块等离子体中射流产生的反应物质的密度和通量(图1)。然后我们研究了从等离子体到液体的反应性转移。由于这一过程通常发生在大的动态时间尺度范围内，等离子体-液体相互作用和液相化学在短(ns)和长(ms)的时间尺度上被考虑。本研究使用二维建模平台nonPDPSIM进行，该平台求解带电和中性物质的输运方程、电势的泊松方程、电子温度的电子能量守恒方程和中性气体流动的Navier-Stokes方程。该模型基本上与[2]中使用的模型相同。反应机理包括He/湿空气和Ar/湿空气的等离子体化学和中性化学以及液相化学。下载:下载高分辨率图像(388KB)下载:下载全尺寸图像图1(a)和(c):氦气和氩气喷入环境空气的流动模式。线上的数字表示氦和氩的摩尔分数。(b)和(d)分别为氦射流和氩射流短等离子体时间尺度下OH自由基的生成。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Clinical Plasma Medicine MEDICINE, RESEARCH & EXPERIMENTAL-

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