|
|
|
|
|
|
| Determination of Nitrite Nitrogen Concentration in Surface Water Based on UV-Vis Spectral Analysis Method |
| LI Qing-bo1, HE Lin-qian1, CUI Hou-xin2, HAO Long-teng2, SUN Dong-sheng2 |
1. Key Laboratory of Precision Opto-Mechatronics Technology, Ministry of Education, School of instrumentation and Optoelectronic Engineering, Beihang University, Beijing 100191, China
2. Hebei Sailhero Environmental Protection Hi-Tech Co., Ltd., Shijiazhuang 050035, China |
|
|
|
|
Abstract With the rapid development of China’s economy, surface water pollution has become increasingly serious. Therefore, it is of vital importance to realize the continuous monitoring of surface water quality to ensure human health and protect the environment. Nitrite nitrogen concentration is an important index in water quality assessment. Polluted water poses a great threat to human, livestock and aquatic products. The detection of organic pollutants by UV-Visible absorption spectrum has become an important method for water quality detection. A few papers about the detection of nitrite nitrogen concentration in water by UV-Vis spectroscopy in China can be found. Most methods require chemical pretreatment of water samples and then use UV spectrophotometer to predict the nitrite nitrogen concentration. These methods are tedious, time-consuming and labor-consuming so thatthey can’t realize real-time continuous detection. Besides, they will cause further environmentpollution. The detection of nitrite nitrogen concentration without chemical pretreatment based on UV-Vis absorption spectrometry is rarely mentioned in the literature. Therefore, UV-Vis spectroscopy was adopted in this paper to carry out basic research on unattended automatic continuous monitoring of surface water quality. Nitrite nitrogen solution samples were preparedand a three-day experiment was designed to measure the ultraviolet and visible spectra of all samples (group D1, group D2, and group D3) respectively every day. Firstly, samples from group D1 and group D2 were modeled respectively by partial least squares regression method (PLSR). The mean absolute percentage error (MAPE) obtained by full cross validation was 1.19% and 1.85% respectively. The result shows that the PLSR model has good prediction accuracy. Secondly, in order to verify the adaptability of PLSR model under different measurement conditions, the experimental data of groupD1 and group D2 were used for mutual prediction analysis. The MAPE was respectively 3.36% and 4.51%, less than 5%, indicating that PLSR model has good robustness. Finally, all samples from groupD1 and group D2 were used for PLSR modeling, and samples from group D3 were used as the test set. The MAPE of the test set was 2.19%. The results show that the MAPE of the PLSR algorithm based on UV-Vis spectral analysis technique for detecting the nitrite nitrogen concentration in solution is controlled under 5%, better than similar reports. In addition, the modeling process of PLSR model is simple and the operation time is short. The model is simple in structure and easier to be transplanted and solidified into embedded systems, bringing convenience to the later development and design of portable devices. As the basic research of the detection of nitrite nitrogencon centration in surface water, this paper can provide guidance for the accurate and rapid detection of surface water quality in the future.
|
|
Received: 2019-06-08
Accepted: 2019-10-12
|
|
|
|
[1] Wang J, Hu M, Zhang F, et al. Stochatic Environmental Research and Risk Assessment, 2018, 32(9): 2633.
[2] WANG Hong-liang, REN Guo-xing, MA Ran, et al(王洪亮, 任国兴, 马 然, 等). Environmental Science & Technology(环境科学与技术), 2010,(s2): 372.
[3] ZHANG Da-fen, TAO Hong-xia, ZHU Ao-lan, et al(张大芬, 陶红霞, 朱敖兰,等). Chinese Journal of Health Laboratory Technology(中国卫生检验杂志), 2015,(5): 639.
[4] YANG Bing, PENG Chuan-you, PENG Bin, et al(杨 兵, 彭传友, 彭 斌, 等). Chinese Journal of Spectroscopy Laboratory(光谱实验室), 2011, 28(6): 2952.
[5] National Standard of the People’s Republic of China(中华人民共和国国家标准). GB 7493—87. Water Quality-Determintion of Nitrogen (Nitrite) Spectrophotometric Method(水质亚硝酸盐氮的测定分光光度法). Beijing: State Environmental Protection Bureau(北京: 国家环境保护局), 1987.
[6] LU Wan-zhen(陆婉珍). Modern Near Infrared Spectroscopy Analytical Technology(现代近红外光谱分析技术). 2nd Ed.(第2版). Beijing: China Petrochemical Press(北京:中国石化出版社), 2007. 44.
[7] Chai T, Draxler R R. Geoscientific Model Development, 2014, 7(3): 1247.
[8] Kim S, Kim H. International Journal of Forecasting, 2016, 32(3): 669. |
| [1] |
LI Yu1, ZHANG Ke-can1, PENG Li-juan2*, ZHU Zheng-liang1, HE Liang1*. Simultaneous Detection of Glucose and Xylose in Tobacco by Using Partial Least Squares Assisted UV-Vis Spectroscopy[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2024, 44(01): 103-110. |
| [2] |
BAO Hao1, 2,ZHANG Yan1, 2*. Research on Spectral Feature Band Selection Model Based on Improved Harris Hawk Optimization Algorithm[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2024, 44(01): 148-157. |
| [3] |
CHEN Jia-wei1, 2, ZHOU De-qiang1, 2*, CUI Chen-hao3, REN Zhi-jun1, ZUO Wen-juan1. Prediction Model of Farinograph Characteristics of Wheat Flour Based on Near Infrared Spectroscopy[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2023, 43(10): 3089-3097. |
| [4] |
XUE Fang-jia, YU Jie*, YIN Hang, XIA Qi-yu, SHI Jie-gen, HOU Di-bo, HUANG Ping-jie, ZHANG Guang-xin. A Time Series Double Threshold Method for Pollution Events Detection in Drinking Water Using Three-Dimensional Fluorescence Spectroscopy[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2023, 43(10): 3081-3088. |
| [5] |
WU Yong-qing1, 2, TANG Na1, HUANG Lu-yao1, CUI Yu-tong1, ZHANG Bo1, GUO Bo-li1, ZHANG Ying-quan1*. Model Construction for Detecting Water Absorption in Wheat Flour Using Vis-NIR Spectroscopy and Combined With Multivariate Statistical #br#
Analyses[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2023, 43(09): 2825-2831. |
| [6] |
LIU Rui-min, YIN Yong*, YU Hui-chun, YUAN Yun-xia. Extraction of 3D Fluorescence Feature Information Based on Multivariate Statistical Analysis Coupled With Wavelet Packet Energy for Monitoring Quality Change of Cucumber During Storage[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2023, 43(09): 2967-2973. |
| [7] |
ZHANG Hai-liang1, XIE Chao-yong1, TIAN Peng1, ZHAN Bai-shao1, CHEN Zai-liang1, LUO Wei1*, LIU Xue-mei2*. Measurement of Soil Organic Matter and Total Nitrogen Based on Visible/Near Infrared Spectroscopy and Data-Driven Machine Learning Method[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2023, 43(07): 2226-2231. |
| [8] |
YAN Zhong-wei1, 2, 3, TIAN Xi2, 3, ZHANG Yi-fei2, 3, LI Lian-jie2, 3, LIU San-qing1, 2, 3, HUANG Wen-qian2, 3*. Online Detection of Soluble Solids Content in Different Parts of
Watermelons Based on Full Transmission Near Infrared
Spectroscopy[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2023, 43(06): 1800-1808. |
| [9] |
CHEN Qing1, TANG Bin1, 2*, LONG Zou-rong1, 2, MIAO Jun-feng1, HUANG Zi-heng1, DAI Ruo-chen1, SHI Sheng-hui1, ZHAO Ming-fu1, ZHONG Nian-bing1. Water Quality Classification Using Convolution Neural Network Based on UV-Vis Spectroscopy[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2023, 43(03): 731-736. |
| [10] |
ZOU Yu-bo1, 2, MA Zhen-yu1, JIAO Qing-bin1, XU Liang1, PEI Jian1, 2, LI Yu-hang1, 2, XU Yu-xing1, 2, ZHANG Jia-hang1, 2, LI Hui1, 2, YANG Lin1, 2, LIU Si-qi1, 2, ZHANG Wei1, 2, TAN Xin1*. Comparative Study on Hyperspectral Inversion Models of Water
Quality Parameters[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2023, 43(03): 949-954. |
| [11] |
WANG Ren-jie1, 2, FENG Peng1*, YANG Xing3, AN Le3, HUANG Pan1, LUO Yan1, HE Peng1, TANG Bin1, 2*. A Denoising Algorithm for Ultraviolet-Visible Spectrum Based on
CEEMDAN and Dual-Tree Complex Wavelet Transform[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2023, 43(03): 976-983. |
| [12] |
ZHANG Yi1, 3, LIU Chuan-yang2, 3, CHENG Cheng2, 3, SHEN Jian2, 3, CHAI Yi-di2, 3, LI Fang2, 3, CHEN Chong-jun1, MEI Juan1*, WU Jing2, 3*. Analysis of Fluorescence Fingerprint Characteristics of Water Quality in the Estuary of the Yangtze River[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2022, 42(12): 3948-3953. |
| [13] |
FENG Hai-kuan1, 2, TAO Hui-lin1, ZHAO Yu1, YANG Fu-qin3, FAN Yi-guang1, YANG Gui-jun1*. Estimation of Chlorophyll Content in Winter Wheat Based on UAV Hyperspectral[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2022, 42(11): 3575-3580. |
| [14] |
LIN Hai-lan1, HUANG Zhong-ting1*, CHEN Yang2, YU Tao1, YANG Yun-bo2, BI Jun-ping1, LIU Pei1. Application of LEFC-2006 in Thallium Monitoring of Water Quality[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2022, 42(11): 3642-3646. |
| [15] |
HU Yu-xia1, CHEN Jie1, SHAO Hui1, YAN Pu1, XU Heng1, SUN Long1, XIAO Xiao1, XIU Lei3, FENG Chun2GAN Ting-ting2, ZHAO Nan-jing2*. Research Progress of Spectroscopy Detection Technologies for Waterborne Pathogens[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2022, 42(09): 2672-2678. |
|
|
|
|
