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通过测量大气压介质阻挡放电等离子体辐射信号,建立偶极子辐射模型,利用快速傅立叶变换,计算了大气压介质阻挡放电等离子体中离子速度分布。计算结果表明,速度分布偏离麦克斯韦分布,并且随着放电过程的进行,离子速度及相对离子数进行有规律的变化。     

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分别采用空气、氩气大气压介质阻挡放电(DBD)等离子体对重油进行了处理.对经空气DBD等离子体处理后的重油进行粘温特性分析,发现重油粘度升高,流动性变差.红外光谱和四组分分析结果表明重油的重质组分含量升高,重油胶体体系被破坏,同时生成大量刺激性气味气体.为了便于分析气态产物的成分和含量,采用大气压氩气DBD等离子体处理重油并收集气体产物.气相色谱分析发现生成气中含有大量C1-C5的烃类和一定量氢气,其中氢气和甲烷含量占生成气的70％以上.实验结果表明重油在等离子体作用下既发生裂解又发生聚合反应,既生成低碳烃类,本身的流动性也变差.     

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在同轴圆柱单介质内外双水冷结构的DBD臭氧发生器的放电间隙内分别填充玻璃珠、高铝瓷、石英砂和熔融石英砂等颗粒,研究填充颗粒材料、粒径大小、间隙宽度等参数对臭氧生成效率的影响.结果表明:颗粒材料的介电常数是影响其臭氧制取效果的主要因素,随着介电常数的增加,间隙击穿电压降低,但由于颗粒导致电场的畸变,间隙折合场强增加,臭氧生成的最大能效降低,饱和浓度提升;高铝瓷具有最高的臭氧饱和浓度,与未填充的空床相比,饱和浓度提升136％;对于填充不同粒径熔融石英砂颗粒,随着粒径的增加,间隙击穿电压上升,间隙的折合场强提高,臭氧生成的最大能效降低,而饱和浓度提升;通过在宽间隙内填充介质颗粒可以得到窄间隙宽度的臭氧制取效果.     

常压射流等离子体发射光谱研究

使用改进介质阻挡放电装置生成常压射流等离子体,采用光纤光栅光谱仪在300～1 000 nm范围记录了不同放电电压的氩气发射光谱,并比较了空气和氩气常压介质阻挡放电等离子体发射光谱,分析发现氩气发射光谱中的谱线都是氩原子的发射谱线,表明常压射流装置产生的等离子体全部为氩等离子体,而无其他空气成分参与放电。为测量电子激发温度,选用相距较近的763.51和772.42 nm两条光谱线对电子温度进行分析,结果表明电子激发温度的范围在0.1～0.3 eV,而且它还随着放电电压的增加而增加。初步使用“红外测温仪”测量被处理材料表面温度,结果发现材料表面的温度也随着放电电压的增加而增加,范围在50～100 ℃,材料表面温度的变化趋势可以近似表征等离子体宏观温度变化趋势。通过分析常压射流等离子体的温度特性,探讨了常压射流等离子体温度对材料改性研究的意义。     

空气介质阻挡放电中氮分子离子的转动温度研究

采用液体电极装置,首次在空气介质阻挡放电中观察到了清晰分辨的氮分子离子第一负带(0,0)转动谱.根据转动光谱的强度分布,确定转动能级上粒子最大布居数位置,估算了氮分子离子的转动温度.改变外加电压和放电气体的气压,研究了转动温度的变化,发现当气压在10.133～60.795 kPa范围时,随电压的增加,谱线强度增加,但其转动光谱的强度分布不变,说明转动温度保持不变.上述结果对于空气介质阻挡放电理论模型的建立及工业应用均具有重要的参考价值.     

大气压氩气/空气介质阻挡放电中分子振动温度

使用水电极介质阻挡放电装置,在氩气和空气混合气体放电中,利用光谱方法测量了氮分子(C3Π_u)的振动温度及其随空气含量的变化关系。计算中采用的是氮分子第二正带系(C3Π_u→B3Π_g)的发射谱线,顺序带组有：Δｖ＝-1,Δｖ＝-2和Δｖ＝-3。结果表明：大气压介质阻挡放电中氮分子振动温度范围为1 938～2 720 K,振动温度随空气含量的增加几乎是线性增加的。该工作对研究介质阻挡放电中等离子体的动力学过程具有重要意义。     

大气压氩气介质阻挡放电中的电子激发温度

采用发射光谱强度比法,测量了大气压氩气介质阻挡放电(DBD)中的电子激发温度。实验在690～800 nm的范围内测量了大气压氩气DBD的发射光谱,经分析发现这些谱线全部是氩原子的发射谱线。为了测量电子激发温度,选用相距较近的763.51 nm(2P₆→1S₅),772.42 nm(2P₂→1S₃)的两条光谱线。结果发现电子温度的范围为0.1～0.5 eV,电子激发温度随电压的增加而增加,随流量的增加而减小。实验还发现氩气流动与非流动时电子激发温度有明显的差别。上述结果对介质阻挡放电在工业领域上的应用具有重要意义。     

离子液体对氩气介质阻挡放电光谱的影响

采用自行设计的介质阻挡放电反应器,以氩气和离子液体为放电介质,实现大气压下稳定的气(等离子体)-液(离子液体)等离子体放电,并运用光谱法在线诊断氩等离子体光谱。考察了不同咪唑基离子液体以及放电参数对大气压氩气介质阻挡放电光谱的影响。结果表明,离子液体的引入降低了氩气放电光谱的强度,谱峰强度与离子液体阳离子咪唑环上的碳链长度有关,且随碳链长度增加,谱峰强度降低;同时阴离子结构对称性低的离子液体,谱峰强度较低。加入离子液体后氩谱随放电电压及放电频率变化均呈现峰值变化。     

圆柱形介质阻挡放电等离子体光谱诊断

在350~1150 nm范围内对开放空间Ar气介质阻挡放电等离子体的发射光谱进行测量,表明Ar发射谱线主要集中在680 nm~950 nm,且都为Ar原子谱线。采用发射光谱相对强度对比法,选取相距较近且有相同下能级的727.29 nm(2P2-1S4),738.40 nm(2P3-1S4)和751.47 nm(2P5-1S4)三条光谱测量电子温度。通过对在Ar气和空气中放电谱线的对比和分析,得出发射光谱相对强度与电源功率的关系。最终得出若要便于工业应用和光谱测量,需要选择特定的气体流量和电源功率。     

一种新型大气压毛细管介质阻挡放电冷等离子体射流技术

介绍一种结构设计简单、操作运行方便的新型毫米量级大气压冷等离子体射流发生技术.这种射流可以在大气压条件下，利用多种工作气体(如Ar,He,N₂)，通过毛细管介质阻挡放电(DBD)的方式实现.使用频率为33kHz，峰值电压为1—12kV的双向脉冲电源，利用Ar,He,N₂等工作气体，在毛细管内形成了稳定的冷等离子体射流.放电区域的光辐射空间分布利用商用CCD摄像机记录，从中研究放电形态和空间分布，观察到了在DBD区域的流动气体放电和在毛细管出口处形成的等离子体射流 关键词： 冷等离子体射流 毛细管介质阻挡放电 射流射程 射流激发温度     

大气压介质阻挡射流放电离子速度分布的测量

通过测量大气压介质阻挡放电等离子体辐射信号,建立偶极子辐射模型,利用快速傅立叶变换,计算了大气压介质阻挡放电等离子体中离子速度分布。计算结果表明,速度分布偏离麦克斯韦分布,并且随着放电过程的进行,离子速度及相对离子数进行有规律的变化。     

Thin-film deposition by combining plasma jet with spark discharge source at atmospheric pressure

This study demonstrates a method for the deposition of CuO_x thin films by combining atmospheric pressure plasma jet with spark discharge. In this type of discharge source, the bulk copper material of spark discharge electrodes plays the role of a precursor. Copper atoms and particles go through the physical processes of sputtering, evaporation, and further agglomeration and condensation in the plasma jet and on the substrate. The experiments were carried out with and without a combination of discharges. The material coated on the substrate was studied using a scanning electron microscope, Raman spectroscopy, and energy-dispersive X-ray spectroscopy. The characteristics of the set-up and plasma, such as I-V curves, optical emission spectra, and substrate temperature, were also measured. Copper electrodes were examined for erosion by a scanning electron microscope. The results demonstrate that deposits coated by combined discharge show denser and thicker films.     

Mechanism and optimization of non-thermal plasma-activated water for bacterial inactivation by underwater plasma jet and delivery of reactive species underwater by cylindrical DBD plasma

Plasma-activated water (PAW) has been in use for the past decade in sanitization against bacteria and other microorganisms. This research study compared PAW generated by a DC positive flyback transformer (FBT) underwater plasma jet with delivery of reactive species underwater by cylindrical dielectric barrier discharge (C-DBD) with a neon transformer. A Box–Behnken design was adopted as a response surface methodology (RSM) to design the experimental plan and optimize operating parameters including time, gas flow, and gas ratio. The physical responses comprise optical emission spectroscopy (OES), pH, oxidation-reduction potential (ORP), and electrical conductivity (EC). The chemical responses consist of hydrogen peroxide (H₂O₂) and hydroxyl radicals (OH·). The biological responses include Escherichia coli reduction and Staphylococcus aureus reduction. The optimal condition for underwater plasma jet was found to be Ar gas with a flow rate of 3 slm for 6.5 min of treatment time, which can reduce E. coli and S. aureus to 7.14 ± 0.14 and 3.10 ± 0.26 in log, respectively. Also, the optimal condition for delivery of reactive species underwater by C-DBD plasma was found to be Ar (99%): O₂ (1%) gas mixture with an Ar gas flow rate of 4 slm for a treatment time of 11.5 min, which could reduce E. coli and S. aureus to 0.45 ± 0.07 and 2.45 ± 0.23 in log, respectively.     

Development of an atmospheric nonthermal multineedle dielectric barrier discharge jet for large area treatment of skin diseases

Nonthermal plasma is suitable for applications in the biomedical field because of the large amounts of active species and a low gas temperature that does not injure the human body. A plasma jet of the typical pen type is applied in most biomedical applications, but it is difficult to apply such jets to treat skin diseases that generally have wide affected areas. In this study, nonthermal multineedle dielectric barrier discharge (DBD) jet was developed for the treatment of large area lesions and used to verify its effectiveness in treating psoriasis as a representative skin disease. Stable discharge was maintained using the developed plasma jet with a multineedle electrode structure by utilizing various discharge gases. Electrical and optical analyses were performed to determine the characteristics of the plasma. The effectiveness of psoriasis treatment using this approach was confirmed by performing in vitro and in vivo experiments with the multineedle DBD jet.     

Aspects of the upstream region in a plasma jet with dielectric barrier discharge configurations

A plasma column with a length of about 65 cm is generated in the upstream region of a plasma jet using dielectric barrier discharge configurations. The effects of experimental parameters such as the amplitude of the applied voltage and the driving frequency are investigated in aspects of the plasma column by the optical method. Results show that both the plasma length and the propagating velocity, as well as the discharge current, increase with the increase in the applied voltage or its frequency. The discharge mechanism is analysed qualitatively based on streamer theory, where photo-ionization is important. Furthermore, optical emission spectroscopy is used to investigate the electric field intensity of the upstream region.     

Aspects of the dielectric upstream region barrier discharge in a plasma jet with configurations

A plasma column with a length of about 65 cm is generated in the upstream region of a plasma jet using dielectric barrier discharge configurations. The effects of experimental parameters such as the amplitude of the applied voltage and the driving frequency are investigated in aspects of the plasma column by the optical method. Results show that both the plasma length and the propagating velocity, as well as the discharge current, increase with the increase in the applied voltage or its frequency. The discharge mechanism is analysed qualitatively based on streamer theory, where photo-ionization is important. Furthermore, optical emission spectroscopy is used to investigate the electric field intensity of the upstream region.     

Corona discharge as a temperature probe of atmospheric air microwave plasma jet

We developed and tested a new method for temperature measurements of near-LTE air plasmas at atmospheric pressure. This method is specifically suitable for plasmas at relatively low gas temperature (800–1700 K) with no appropriate radiation for direct spectroscopic temperature measurements. Corona discharge producing cold non-equilibrium plasma is employed as a source of excitation and is placed into the microwave plasma jet. The gas temperature of the microwave plasma jet is determined as the rotational temperature of N₂? produced in the corona discharge. The corona probe temperature measurement was tested by the use of a thermocouple. We found a fairly good agreement between the two methods after correcting the thermocouple measured temperatures for radiative losses. The corona probe method can be generally applied to determine the temperature of the near-LTE plasmas and contrary to the thermocouple it can be used for higher plasma temperatures and is not affected by radiative losses and problems of interaction with the microwave plasma and electromagnetic fields.     

不同时空结构的四边形放电斑图等离子体参量研究

采用发射光谱法,研究了不同时空结构四边形斑图的等离子体参量。实验发现,在低气压区和高气压区,四边形斑图表现出不同的时空结构。利用N₂分子第二正带系的六条谱线强度计算了分子振动温度;利用第一负带系N+₂(391.4 nm)与第二正带系N₂(394.1 nm)谱线强度比,研究了电子能量的变化;利用Ar原子696.54 nm谱线的展宽和频移来反映电子密度;利用Ar原子特征谱线强度比法计算了电子激发温度。结果表明：低气压区四边形斑图的分子振动温度、电子激发温度和电子平均能量均大于高气压区四边形斑图,而电子密度小于高气压区四边形的电子密度。