Study on Emission Spectrum of Radicals in Remediation System of Polluted Soil with Pulsed Discharge Plasma in Oxygen
ZHOU Guang-shun1, WANG Hui-juan1, 2*,WU Qiang-shun1, GUO He1
1. School of the Environment and Safety Engineering, Jiangsu University, Zhenjiang 212013, China 2. Collaborative Innovation Center of Technology and Material of Water Treatment, Suzhou 215009, China
Abstract:Based on the advantage of spectroscopy method and the significant effect of ·OH and ·O in advanced oxidation degradation system, the change of relative emission spectra intensities of the ·OH and the ·O in a pulsed discharge plasma (PDP) system bubbled with oxygen were tested by using the spectrum detecting technique in this research. The PDP system with needle-to-net electrode was set up in the paper to remediate the polluted soil. The relative emission spectra intensities of the ·OH and the ·O formed in the PDP system with oxygen (O2) bubbling were detected with the spectrograph to illustrate the critical effect of the ·OH and the ·O on the organic compound degradation in the PDP system. The changes of the relative emission spectra intensities of the ·OH and the ·O under the conditions of without soil addition, with the original soil addition, with the organic compound polluted soil addition and with the organic compound-heavy metal polluted soil addition were firstly investigated in the paper. The effect of peak pulse voltage, electrode gap and O2 flow rate on the relative emission spectra intensities of the ·OH and the ·O were also studied to explain the changing rule of the active species in the PDP system. The obtained results show that the addition of soil are beneficial to the formation of the ·OH and the ·O in PDP system for the soil remediation. The relative emission spectra intensities of the ·OH and the ·O in the PDP system with organic compounds polluted soil addition were lower than those in the PDP system with the original soil addition, which proved the oxidation of the ·OH and the ·O on the organic compounds degradation in the remediation system, and the addition of heavy metal ions were favorable to the degradation of the organic compounds in the PDP system. Furthermore, the increase of the peak pulse voltage as well as theO2 flow rate was in favor of the formation of the ·OH and the ·O, while the relative emission spectra intensities of the ·OH and the ·O were lower under the condition of the higher electrode gap, which demonstrated that the higher electrode gap were not in favor of the active species formation. In the study, based on the description of the pivotal role of ·OH and the ·O in the PDP system for the polluted soil remediation, the influence rule of the main factors during the process of polluted soil remediation in the PDP system on the content of ·OH and the ·O were analyzed. This research will provide some basic experimental evidence for the application of PDP technology on the polluted soil remediation.
Key words:Pulsed discharge plasma;Remediation of the polluted soil;·OH;·O;Spectrum analysis
周广顺1,王慧娟1, 2*,吴强顺1,郭 贺1 . 载氧环境下脉冲放电等离子体修复污染土壤体系中自由基的发射光谱 [J]. 光谱学与光谱分析, 2017, 37(03): 896-901.
ZHOU Guang-shun1, WANG Hui-juan1, 2*,WU Qiang-shun1, GUO He1 . Study on Emission Spectrum of Radicals in Remediation System of Polluted Soil with Pulsed Discharge Plasma in Oxygen. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2017, 37(03): 896-901.
[1] Geng Cong, Wu Chundu, Wang Huijuan, et al. Journal of Electrostatics, 2015, 73: 38. [2] ZHU Tao, WAN Yan-dong, LI Jian, et al(竹 涛,万艳东,李 坚,等). Journal of Chemical Engineering of Chinese Universities(高校化学工程学报), 2011, 1: 161. [3] DONG Bing-yan, ZHOU Hai-jin, NIE Ya-lin, et al(董冰岩,周海金,聂亚林,等). High Voltage Engineering(高电压技术), 2016, 42(2): 377. [4] Wang Huijuan, Guo He, Wu Qiangshun, et al. Vacuum, 2016, 128: 99. [5] Wang Huijuan, Guo He, Liu Yongjie, et al. Plasma Science and Technology, 2015, 17(10): 881. [6] Peurrung Loni M, Peurrung Anthony J. Journal of Physics D: Applied Physics, 1997, 30(3): 432. [7] Wang Huijuan, Zhou Guangshun, Guo He, et al. Journal of Electrostatics, 2016, 80: 69. [8] WANG Hui-juan, GUO He, ZHAO Wen-xin, et al(王慧娟,郭 贺,赵文信,等). High Voltage Engineering(高电压技术), 2015, 41(10): 3512. [9] FU Yan, WANG Ai-xiang, MA Dong-ping, et al(付 燕,王爱香,马东平). Journal of Northwest Normal University Natural Science(西北师范大学学报·自然科学版), 2007, 43(3): 49. [10] FANG Guang-rong, LIU Li-ming, LI Ling, et al(方光荣,刘立明,李 玲,等). Journal of Analytical Science(分析科学学报), 2004, 20(1): 64. [11] WANG Hai-yan, JIANG Zhan-peng, YANG Hong-wei(王海燕,蒋展鹏,杨宏伟). Chinese Journal of Environmental Engineering(环境工程学报), 2008, 2(2): 225. [12] CHU Jin-yu, XU Hui-lan, ZHOU Jian-jun(储金宇,徐会兰,周建军). Environmental Science & Technology(环境科学与技术), 2008, 31(10): 76. [13] GENG Rong, ZHAO Guo-hua, LIU Mei-chuan, et al(耿 榕,赵国华,刘梅川,等). Acta Phys. Chim. Sin.(物理化学学报), 2010, 26(6): 1493. [14] Guo He, Wang Huijuan, Wu Qiangshun, et al. Chemosphere, 2016, 159: 221.
