|
|
|
|
|
|
Distribution of DOM in Soil Profiles Under Different Types of Organic Fertilizer During the Growth Period of Lettuce |
PAN Hong-wei, CHEN Hui-ru, SHI Li-li, LEI Hong-jun*, WANG Yi-fei, KONG Hai-kang, YANG Guang |
School of Water Conservancy, North China University of Water Resources and Electric Power, Zhengzhou 450046, China
|
|
|
Abstract The application of organic fertilizer is an effective way to improve the quality and efficiency of crop production. Studying the distribution of dissolved organic matter (DOM) in soil profiles under the application of organic fertilizer from different sources is helpful to optimize the utilization of organic fertilizer and further understand the environmental behavior of DOM. This paper used 2D correlation spectroscopy (2D-COS) to study the effects of different organic fertilizers (pig manure, chicken manure, sheep manure, cow manure, and biogas residue) on DOM distribution in the soil profile. The results showed that organic fertilizer return to the field mainly affected the soil's relative content and composition of DOM. After applying different organic fertilizers, the relative content of DOM in soil was always higher than that in control (CK) treatment, and the relative content of DOM in the 0~10 cm soil layer had the greatest effect, with an average increase of 14.67 g·kg-1. Different types of organic fertilizer had a certain difference in the increase of profile DOM, among which chicken manure organic fertilizer had the greatest effect on the increase of profile DOM, increasing by 21.42%. The application of organic fertilizer mainly increased the relative content of tyrosine-like components (C4), and had the greatest impact on the relative content of C4 in the 10~20 cm soil layer, with an average increase of 4.12%, in which sheep manure and biogas residue had the greatest impact, with an increase of 7.80% and 7.89%, respectively. 2D-COS analysis showed that applying organic fertilizer from different sources greatly impacted dissolved microbial metabolites and protein-like components (295, 315 nm); CK and chicken manure treatment mainly affected dissolved microbial metabolites, and other treatments first responded to protein-like components. The humification index HIX, Fn(330) and Fn(280) decreased with the increase of soil depth. Still, the changes of HIX, Fn(330), and Fn(280) were different with different types of organic fertilizer, among which cow manure had the greatest effect on HIX and Fn(330). Sheep manure had the greatest effect on Fn(280). The biological index BIX and freshness index β∶α increased with the increase of soil depth, and the influence of biogas residue was the most significant. Still, the fluorescence index FI had no significant change.
|
Received: 2023-08-29
Accepted: 2024-03-01
|
|
Corresponding Authors:
LEI Hong-jun
E-mail: hj_lei2002@163.com
|
|
[1] Yan L L, Liu C, Zhang Y D, et al. Ecotoxicology and Environmental Safety, 2021, 209: 111804.
[2] ZHAO Xiong-wei, WU Dong-ming, LI Qin-fen, et al(赵雄威, 吴东明, 李勤奋, 等). Spectroscopy and Spectral Analysis(光谱学与光谱分析), 2022, 42(10): 3210.
[3] Li J W, Zhao L Y, Li M, et al. Ecological Indicators, 2022, 143: 109386.
[4] Tan Z H, Dong B, Xing M Y, et al. Environmental Technology, 2024, 45(2): 283.
[5] LI Zhang-hai, ZHU Kai, PENG Yu, et al(李章海, 朱 凯, 彭 宇, 等). Chinese Tobacco Science(中国烟草科学), 2016, 37(3): 40.
[6] Xu R Z, Cao J S, Feng G Y, et al. Chemical Engineering Journal, 2022, 430(2): 132893.
[7] HOU Lei, WU Pei-yi(侯 磊, 武培怡). Acta Polymerica Sinica(高分子学报), 2022, 53(5): 522.
[8] LIANG Yi-hao, NI Cai-ying, LIU Xing-xing, et al(梁以豪, 倪才英, 刘星星, 等). Chinese Journal of Eco-Agriculture(中国生态农业学报),2023, 31(4): 543.
[9] WANG Xing-yu, ZHANG Xi, DING Jing-tao, et al(王鑫宇, 张 曦, 丁京涛, 等). Journal of Agro-Environment Science(农业环境科学学报), 2021, 40(11): 2372.
[10] Chen W, Habibul N, Liu X Y, et al. Environmental Science & Technology, 2015, 49(4): 2052.
[11] LIN Shao-xia, XIAO Zhi-qiang, ZHANG Zhuan-ling, et al(林绍霞, 肖致强, 张转铃, 等). China Environmental Science(中国环境科学), 2021, 41(3): 1325.
[12] Coulson L E, Weigelhofer G, Gill S, et al. Biogeochemistry, 2022, 159(2): 159.
[13] Pucher M, Flödl P, Graeber D, et al. Biogeosciences, 2021, 18(10): 3103.
[14] Yamashita Y, Scinto L J, Maie N, et al. Ecosystems, 2010, 13(7): 1006.
[15] D'Andrilli J, Junker J R, Smith H J, et al. Biogeochemistry, 2019, 142(2):281.
[16] Yan C X, Sheng Y R, Ju M, et al. Environmental Science and Pollution Research, 2020, 27(25):31872.
[17] TIAN Kai, LI Jia-qian, HAO Qiang, et al(田 凯, 黎佳茜, 郝 强, 等). Chinese Journal of Environmental Engineering(环境工程学报), 2022, 16(10): 3497.
[18] LÜ Jing-jing, GONG Wei-jin, DOU Yan-yan, et al(吕晶晶, 龚为进, 窦艳艳, 等). China Environmental Science(中国环境科学), 2019, 39(5): 2039.
[19] HONG Zhi-qiang, XIONG Ying, LI Yan, et al(洪志强, 熊 瑛, 李 艳, 等). Acta Ecologica Sinica(生态学报), 2016, 36(19): 6308.
[20] Huguet A, Vacher L, Saubusse S, et al. Organic Geochemistry, 2009, 40(6): 706.
[21] XIAO Long-geng, CHEN Wen-song, CHEN Guo-feng, et al(肖隆庚, 陈文松, 陈国丰, 等). Acta Scientiae Circumstantiae(环境科学学报), 2014, 34(1): 160.
[22] Huguet A, Vacher L, Saubusse S, et al. Organic Geochemistry, 2010, 41(6): 595.
[23] Ohno T. Environmental Science & Technology, 2002, 36(4): 742.
[24] Lavonen E E, Kothawala D N, Tranvik L J, et al. Water Research, 2015, 85: 286.
[25] Mcknight D M, Boyer E W, Westerhoff P K, et al. Limnology and Oceanography, 2001, 46(1): 38.
|
[1] |
ZHANG Wei-wei, QU Yi, WANG Qiang, LÜ Ri-qin, GU Hai-yang, SHAO Juan, SUN Yan-hui*. Research on the Synchronous Fluorescence Spectroscopy Combined With Support Vector Machines for Intelligent Discrimination of Milk
Adulteration[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2024, 44(09): 2428-2433. |
[2] |
ZHANG Ying-chao1, 2, 3, BI Zhi-tao1, TIAN Wen-xin1, XU Rui2, TANG Shou-feng1, SHI Hong-ying4, ZHANG Hong-qiong5*. Impact of Different Oxygen Concentrations on the Spectral Characteristics of Iron Oxide-Enhanced Abiotic Humification Products[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2024, 44(06): 1620-1626. |
[3] |
XIONG Qiu-ran1, 2, SHEN Jian1, 2, HU Yuan2, 3, CHAI Yi-di1, 2, 3, GU Yi-qin2, 3, LENG Xiao-ting2, 3, CHENG Cheng1, 2, WU Jing1, 2*. Study on Pollution Source Identification of Composite Polluted River Based on Aqueous Fluorescence Fingerprint Technology[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2024, 44(06): 1773-1780. |
[4] |
WU Zhuo-hui1, 3, HUANG Bing-jia1, 3, LI Xue-qin1, 3, WANG Xiao-ping1, 2, 3*. A Self-Adapting Method for Removing Scatterings in the
Excitation-Emission Matrix Spectroscopy[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2024, 44(04): 969-976. |
[5] |
CHENG Peng-fei1,ZHU Yan-ping2*,PAN Jin-yan1,CUI Chuan-jin2,ZHANG Yi2. Classification of Oil Pollutants by Three-Dimensional Fluorescence
Spectroscopy Combined With IGOA-SVM[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2024, 44(04): 1031-1038. |
[6] |
ZHANG Jing, WANG Hong-hui, JIN Liang, LIAO Ying-min, LI Heng. Effects of 9-Hydroxyphenanthrene on α-Glucosidase Activity and Their Binding Interactions[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2024, 44(02): 398-405. |
[7] |
WANG Hai-zhen1, 2, 3, GUO Jian-fen1, 2, 3*, ZHANG Lei1, 2, 3, LIN Hao1, 2, 3, LIN Jing-wen1, XIONG De-cheng1, 2, 3, CHEN Shi-dong1, 2, 3, YANG Yu-sheng1, 2, 3. Composition and Spectral Characteristics of Soil Dissolved Organic Matter Leachate From Different Planted Tree Species[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2024, 44(02): 490-496. |
[8] |
GU Yi-lu1, 2,PEI Jing-cheng1, 2*,ZHANG Yu-hui1, 2,YIN Xi-yan1, 2,YU Min-da1, 2, LAI Xiao-jing1, 2. Gemological and Spectral Characterization of Yellowish Green Apatite From Mexico[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2024, 44(01): 181-187. |
[9] |
LEI Hong-jun1, YANG Guang1, PAN Hong-wei1*, WANG Yi-fei1, YI Jun2, WANG Ke-ke2, WANG Guo-hao2, TONG Wen-bin1, SHI Li-li1. Influence of Hydrochemical Ions on Three-Dimensional Fluorescence
Spectrum of Dissolved Organic Matter in the Water Environment
and the Proposed Classification Pretreatment Method[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2024, 44(01): 134-140. |
[10] |
XIA Ming-ming1, 2, LIU Jia3, WU Meng1, 2, FAN Jian-bo1, 2, LIU Xiao-li1, 2, CHEN Ling1, 2, MA Xin-ling1, 2, LI Zhong-pei1, 2, LIU Ming1, 2*. Three Dimensional Fluorescence Characteristics of Soluble Organic Matter From Different Straw Decomposition Products Treated With Calcium Containing Additives[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2024, 44(01): 118-124. |
[11] |
SONG Yi-ming1, 2, SHEN Jian1, 2, LIU Chuan-yang1, 2, XIONG Qiu-ran1, 2, CHENG Cheng1, 2, CHAI Yi-di2, WANG Shi-feng2,WU Jing1, 2*. Fluorescence Quantum Yield and Fluorescence Lifetime of Indole, 3-Methylindole and L-Tryptophan[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2023, 43(12): 3758-3762. |
[12] |
YANG Ke-li1, 2, PENG Jiao-yu1, 2, DONG Ya-ping1, 2*, LIU Xin1, 2, LI Wu1, 3, LIU Hai-ning1, 3. Spectroscopic Characterization of Dissolved Organic Matter Isolated From Solar Pond[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2023, 43(12): 3775-3780. |
[13] |
HUANG Li, MA Rui-jun*, CHEN Yu*, CAI Xiang, YAN Zhen-feng, TANG Hao, LI Yan-fen. Experimental Study on Rapid Detection of Various Organophosphorus Pesticides in Water by UV-Vis Spectroscopy and Parallel Factor Analysis[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2023, 43(11): 3452-3460. |
[14] |
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. |
[15] |
JIA Yu-ge1, YANG Ming-xing1, 2*, YOU Bo-ya1, YU Ke-ye1. Gemological and Spectroscopic Identification Characteristics of Frozen Jelly-Filled Turquoise and Its Raw Material[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2023, 43(09): 2974-2982. |
|
|
|
|