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大气压等离子体射流具有广阔的应用前景, 而电压、气体流速、外磁场均会影响其性能, 其综合影响更会使得放电规律复杂化. 但是目前缺乏三者组合对射流特性的综合影响研究, 无法更全面评估多放电条件下的放电特性规律. 因此, 本文以交流氩气等离子体射流为对象, 研究了电压、外磁场、气体流速三者组合作用对放电的宏观形貌、功率、气体温度、电子激发温度、电子密度、$\rm Ar^* $光谱强度、·OH粒子数密度等参量的影响. 结果表明, 电压对射流参量的影响规律不受气体流速和外磁场的影响, 增大电压能提升放电性能; 加入外磁场可以在不引起放电功率显著变化的情况下提升放电性能, 尤其是当磁场仅作用于等离子羽时, 提升效果最显著; 气体流速对射流性能的改变会受到电压和外磁场的影响, 并不是在单个放电条件最优的组合情况下取得最佳的射流性能. 本研究有助于更全面了解不同放电条件下射流特性, 为优化射流性能提供指导, 有利于推动大气压等离子体射流技术的发展.Atmospheric pressure plasma jet has received widespread attention due to its enormous potential applications in various fields, and its discharge conditions play a key role in changing their physical and chemical properties and ultimately determining its application effectiveness. Factors such as discharge voltage, gas flow rate, and the introduction of an external magnetic field intricately influence the performance of plasma jet. The combined effects of any two of these factors can yield enhanced outcomes, while also bringing complexity to the discharge phenomenon. However, there is currently a lack of research on the combined effects of external magnetic field, discharge voltage, and gas flow rate on the characteristics of plasma jets, making it difficult to comprehensively evaluate the discharge characteristics of plasma jet under multiple discharge conditions. Therefore, this paper focuses on an AC excited atmospheric pressure argon plasma jet and investigates the combined effects of external magnetic field, discharge voltage, and gas flow rate on various characteristic parameters of the plasma jet, including macroscopic morphology, discharge power, gas temperature Tg, electron excitation temperature Texc, electron density ne, emission intensity of excited state Ar* particles, and number density of ground state ·OH particles by using methods of camera shooting, and electrical parameter measurement, spectroscopic analysis of emission and absorption spectra. The obtained results are shown below. The effect of discharge voltage on the characteristic parameters of the plasma jet is not affected by gas flow rate or the existence of an external magnetic field. The increase of discharge voltage can improve jet performance by enhancing the discharge power, extending the plasma plume length, elevating the gas temperature Tg and electron excitation temperature Texc, increasing the electron density ne and emission intensity of excited state Ar* particles, as well as the number density of ground state ·OH particles. The addition of an external magnetic field can improve the jet performance without significantly changing the discharge power, and the extent of this improvement is influenced by the mode of magnetic field action. Notably, the enhancement of jet performance is most significant when the magnetic field selectively targets the plasma plume, excluding direct interaction with electrode discharge region. The effect of gas flow rate on jet performance becomes intricate: it is intertwined with the effect of voltage and the effect of external magnetic field. When an external magnetic field is present, excessive voltage and gas flow rate may reduce the number density of ground state ·OH particles generated by plasma jet. This underscores the need for a detailed understanding when optimizing jet performance under various discharge conditions. Simply combining the optimal conditions for each individual factor does not guarantee the achievement of peak jet performance when all three discharge conditions work synergistically. This study presents valuable insights into the discharge characteristics of plasma jet under different discharge conditions, providing guidance for optimizing the performance of plasma jet and promoting the advancement of atmospheric pressure plasma jet technology in different application fields.
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Keywords:
- atmospheric pressure plasma jet /
- plasma characteristics /
- reactive species /
- external magnetic field
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图 1 (a) APPJ实验装置; (b) 磁场系统
Fig. 1. (a) Experimental setup of APPJ; (b) magnetic field system.
图 2 (a)发射光谱图; (b)计算电子密度示意图; (c)计算电子激发温度示意图; (d)计算气体温度示意图
Fig. 2. (a) Diagram for optical emission spectrum; (b) diagram for electron density calculation; (c) diagram for electron excitation temperature calculation; (d) diagram for gas temperature calculation.
图 3 (a) APPJ放电形貌; (b) 等离子体羽长度随放电条件的变化
Fig. 3. (a) APPJ discharge morphology; (b) variation of plume length with discharge conditions.
图 5 (a)气体温度和(b)电子激发温度随放电条件的变化
Fig. 5. Variation of (a) gas temperature and (b) electron excitation temperature with discharge conditions.
图 6 电子密度随放电条件的变化
Fig. 6. Variation of electron number density with discharge conditions.
图 7 (a)激发态Ar*光谱强度和(b)基态·OH粒子数密度随放电条件的变化
Fig. 7. Variation of (a) excited Ar* spectral intensity and (b) ·OH number density with discharge conditions.
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[1] Ma L, Chen Y, Gong Q, Cheng Z, Ran C F, Liu K, Shi C M 2023 Free Rad. Biol. Medic. 204 184
Google Scholar
[2] Wang X L, Liu J, Li Q X, Li L, Li S R, Ding Y H, Zhao T, Sun Y, Zhang Y T 2023 High Volt. 8 841
Google Scholar
[3] Xi D K, Zhang X H, Yang S Z, Yap S S, Ishikawa K, Hori M, Yap S L 2022 Chin. Phys. B 31 128201
Google Scholar
[4] Kong X H, Xue S, Li H Y, Yang W M, Martynovich E F, Ning W J, Wang R X 2022 Plasma Sources Sci. Technol. 31 095010
Google Scholar
[5] Cui X L, Xu Z B, Zhou Y Y, Zhu X, Wang S, Fang Z 2022 Surf. Coat. Technol. 451 129066
Google Scholar
[6] 孔得霖, 杨冰彦, 何锋, 韩若愚, 缪劲松, 宋廷鲁, 欧阳吉庭 2021 物理学报 70 095205
Google Scholar
Kong D L, Yang B Y, He F, Han R Y, Miao J S, Song T L, Ouyang J T 2021 Acta Phys. Sin. 70 095205
Google Scholar
[7] Wang R Y, Shen J Y, Ma Y P X, Qin X R, Qin X, Yang F, Ostrikov K, Zhang Q, He J, Zhong X X 2024 Plasma Process. Polym. 21 2300174
Google Scholar
[8] Liu K, Ren W, Ran C F, Zhou R S, Tang W B, Zhou R W, Yang Z H, Ostrikov K 2021 J. Phys. D: Appl. Phys. 54 065201
Google Scholar
[9] Liu Z J, Wang S T, Pang B L, Gao Y T, Li Q S, Xu D H, Liu D X, Zhou R W 2022 Plasma Sources Sci. Technol. 31 05LT03
Google Scholar
[10] Guo L, Xu R B, Guo L, Liu Z C, Zhao Y M, Liu D X, Zhang L, Chen H L, Kong M G 2018 Appl. Environ. Microbiol. 84 e00726-18
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[11] Ran C F, Zhou X F, Wang Z Y, Liu K 2024 Plasma Sources Sci. Technol. 33 015009
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[12] Liu K, Geng W Q, Zhou X F, Duan Q S, Zheng Z F, Ostrikov K 2023 Plasma Sources Sci. Technol. 32 025005
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[13] Liu K, Zuo J, Ran C F, Yang M H, Geng W Q, Liu S T, Ostrikov K 2022 Phys. Chem. Chem. Phys. 24 8940
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[14] Xu H M, Gao J G, Jia P Y, Ran J X, Chen J Y, Li J M 2024 Chin. Phys. B 33 015205
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[15] 陈忠琪, 钟安, 戴栋, 宁文军 2022 物理学报 71 165201
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Chen Z Q, Zhong A, Dai D, Ning W J 2022 Acta Phys. Sin. 71 165201
Google Scholar
[16] Huang B D, Zhang C, Zhu W C, Lu X P, Shao T 2021 High Volt. 6 665
Google Scholar
[17] Wang B H, Chen L, Liu G M, Song P, Cheng F C, Sun D L. Zeng W, Xu L 2023 Phys. Scr. 98 045612
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[18] Chen M, Dong X P, Wu K Y, Ran J X, Jia P Y, Wu J C, Li X C 2024 Appl. Phys. Lett. 124 214102
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Tian F C, Chen L, Pei H, Bai J Q, Zeng W 2023 Spectros. Spect. Anal. 43 3682
Google Scholar
[22] Jurov A, Skoro N, Spasic K, Modic M, Hojnik N, Vojosevic D, Durovic M, Petrovic Z L, Cvelbar U 2022 Eur. Phys. J. D 76 29
Google Scholar
[23] Bousba H E, Sahli S, Namous W S E, Benterrouche L 2022 IEEE Trans. Plasma Sci. 50 1218
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Google Scholar
[25] 刘坤, 杨明昊, 周雄峰, 白杨, 冉从福 2023 高等学校化学学报 44 20230327
Google Scholar
Liu K, Yang M H, Zhou X F, Bai Y, Ran C F 2023 Chem. J. Chin. Universities 44 20230327
Google Scholar
[26] Jiang W M, Tang J, Wang Y S, Zhao W, Duan Y X 2014 Appl. Phys. Lett. 104 013505
Google Scholar
[27] Liu C T, Kumakura T, Ishikawa K, Hashizume H, Takeda K, Ito M, Hori M, Wu J S 2016 Plasma Sources Sci. Technol. 25 065005
Google Scholar
[28] Xu H, Guo S S, Zhang H, Liu D X, Xie K 2021 Phys. Plasmas 28 123521
Google Scholar
[29] Sah A K, Al-Amin M, Talukder M R 2023 Environ. Sci. Pollut. Res. 30 74877
Google Scholar
[30] Guo H F, Xu Y F, Wang Y Y, Ren C S 2020 Phys. Plasmas 27 023519
Google Scholar
[31] Wang M Y, Han R Y, Zhang C Y, Ouyang J T 2020 IEEE International Conference on High Voltage Engineering and Application Beijing, China, September 6–10, 2020 pp1–4
[32] Liu K, Xia H T, Yang M H, Geng W Q, Zuo J, Ostrikov K 2022 Vacuum 198 110901
Google Scholar
[33] 刘坤, 左杰, 周雄峰, 冉从福, 杨明昊, 耿文强 2023 物理学报 72 055201
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Liu K, Zuo J, Zhou X F, Ran C F, Yang M H, Geng W Q 2023 Acta Phys. Sin. 72 055201
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Liu K, Xiang H F, Zhou X F, Xia H T, Li H 2023 Acta Phys. Sin. 72 115201
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Google Scholar
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Google Scholar
[38] Ran C F, Zhou X F, Liu K 2024 Phys. Chem. Chem. Phys. 26 18408
Google Scholar
[39] Dang V S M M, Foucher E, Rousseau A 2015 J. Phys. D: Appl. Phys. 48 424003
Google Scholar
[40] Zhou X F, Xiang H F, Yang M H, Geng W Q, Liu K 2023 J. Phys. D: Appl. Phys. 56 455202
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[41] Chen J Y, Zhao N, Wu J C, Wu K Y, Zhang F R, Ran J X, Jia P Y, Pang X X, Li X C 2022 Chin. Phys. B 31 065205
Google Scholar
[42] Gudmundsson J T, Thorstinsson E G 2007 Plasma Sources Sci. Technol. 16 399
Google Scholar
[43] Sakiyama Y, Graves D B, Chang H W, Shimuzu T, Morfill G E 2012 J. Phys. D: Appl. Phys. 45 425201
Google Scholar
[44] Tian W, Tachibana K, Kushner M J 2014 J. Phys. D: Appl. Phys. 47 055202
Google Scholar
[45] Jiang N, Sun Y, Peng B F, Li J, Shang K F, Lu N, Wu Y 2022 Plasma Process. Polym. 19 e2100108
Google Scholar
[46] 胡杨, 罗婧怡, 蔡雨烟, 卢新培 2023 物理学报 72 130501
Google Scholar
Hu Y, Luo J Y, Cai Y Y, Lu X P 2023 Acta Phys. Sin. 72 130501
Google Scholar
[47] Singh K S, Sharma A K 2021 J. Appl. Phys. 130 043302
Google Scholar
[48] Jeroen J, van de Sande M, Sola A, Gamero A, Rodero A, van der Mullen J 2003 Plasma Sources Sci. Technol. 12 464
Google Scholar
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