大气压等离子体射流中重复脉冲产生的活性氧和活性氮

Seth A. Norberg, E. Johnsen, M. Kushner
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引用次数: 2

摘要

只提供摘要形式。活性氧和活性氮(RONS)在许多应用中都是需要的,从破坏有害蛋白质和细菌在医疗领域的灭菌,到利用O2的亚稳特性(1 Δ)将能量转移到其他物种。近年来在大气压等离子体射流方面的进展表明,使用这种技术作为RONS来源的可能性。等离子体射流由直径小(几毫米)的管道组成,稀有气体混合物(例如,He注入了百分之几的O2)通过这些管道流入室内空气中。它们通常在介质阻挡放电(DBD)配置中操作,该配置产生电离波(或等离子体子弹),重复频率为许多kHz到数十或数百MHz。在本文中,我们报告了由He/O2混合物组成的重复脉冲等离子体射流在许多kHz到许多MHz的频率上排放到环境空气中产生RONS的计算研究结果。本研究中使用的计算机模型,nonPDPSIM,解决了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,以及中性气体流动的Navier-Stokes方程。体等离子体的速率系数和输运系数由电子能量分布的玻尔兹曼方程的局部解求得。脉冲间隔周期的长短对等离子体射流流出液中粒子束的密度和分布有显著影响。在高重复率下(产生比气体清除时间短的脉冲间隔周期),在脉冲对脉冲的基础上,羽流中有ron的积累,使这些物种之间能够进一步反应。下一个脉冲的电离波采样前一个脉冲产生的反应环境。在较低的重复频率下,脉冲间隔时间等于或长于气体通过装置的清除时间。在这些情况下,电离波进入一个更原始和可控的环境。
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Reactive oxygen and nitrogen species (RONS) produced by repetitive pulses in atmospheric pressure plasma jets
Summary form only given. Reactive oxygen and nitrogen species (RONS) are desired in numerous applications from the destruction of harmful proteins and bacteria for sterilization in the medical field to taking advantage of the metastable characteristics of O2(1 Δ) to transfer energy to other species. Advances in atmospheric pressure plasma jets in recent years have shown the possibility of using this technology as a source of RONS. The plasma jets consist of small diameter tubes (a few mm) through which rare gas mixtures (e.g., He seeded with a few percent of O2) are flowed into room air. They are typically operated in a dielectric barrier discharge (DBD) configuration which produces an ionization wave (or plasma bullet) with repetition rates of many kHz to tens or hundreds of MHz. In this paper, we report on results of a computational investigation of the production of RONS from repetitively pulsed plasma jets at frequencies from many kHz to many MHz consisting of He/O2 mixtures discharged into ambient air. The computer model used in this study, nonPDPSIM, 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. Rate coefficients and transport coefficients for the bulk plasma are obtained from local solutions of Boltzmann's equation for the electron energy distribution. The length of the interpulse period has significant effects on the density and distribution of the RONS in the effluent of the plasma jet. At high repetition rates (producing interpulse periods shorter than the gas clearing time), there is accumulation of RONS in the plume on a pulse-to-pulse basis, enabling further reactions between these species. The ionization wave of the following pulse samples the reactive environment produced by the previous pulse. At lower repetition rates, the interpulse periods are commensurate or longer than the clearing time of the gas through the device. In these cases, the ionization wave enters a more pristine and controllable environment.
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