Effects of freeze-thaw and soil moisture on content and spectral structure properties of dissolved organic matter in forest soil leachates.

doi:10.13287/j.1001-9332.201909.005

Abstract

Abstract: The contents and stability of soil dissolved organic matter (DOM) can affect key processes of soil carbon and nitrogen cycle. The responses of DOM content and its spectral structure pro-perties in forest soils to climate change remain unclear. We collected soil samples from two temperate forests, i.e., the broadleaf and Korean pine mixed forest (BKPF) and adjacent secondary white birch forest (WBF), in Changbai Mountains, northeastern China. Using a combination of three-dimensional fluorescence spectrum and parallel factor analysis, a simulated freeze-thaw experiment was conducted in the laboratory. We examined the effects of freeze-thaw intensity, freeze-thaw cycle and their interaction on the content, components and spectral properties of DOM leached from the two forest surface soils with different moisture levels. The results showed that DOM content and components of soil leachates varied with forest types, soil moisture, freeze-thaw intensity and freeze-thaw cycle. The DOM content in the leachates was lowest at medium moisture level and was significantly affected by the high freeze-thaw intensity. In addition, the DOM content increased first and then decreased with the increases of freeze-thaw cycles. Three fluorescence components of DOM in the forest soil leachates were identified as humic acid-like DOM, fulvic acid-like DOM and protein-like DOM. The DOM components of BKPF soil leachates were mainly consisted of fulvic acid-like substances with a high humification index. However, the DOM from WBF soil leachates was dominated by humic acid-like substances with low stability, and the three fluorescence components were significantly affected by the freeze-thaw intensity. Results from the redundancy analysis showed that under the experimental conditions, forest type played a leading role in changing DOM properties. The DOM content and its three fluorescence intensities of WBF soil leachates were higher than those of BKPF. Soil moisture significantly affected the aromaticity of DOM in the forest soil leachates, and the DOM aromaticity of soil leachates from the two forest stands ranked as medium moisture > high moisture > low moisture. With the increases of freeze-thaw intensity, the DOM aromaticity of BKPF soil leachates significantly decreased. Furthermore, the increases of freeze-thaw cycles significantly increased the humification degree of DOM in the forest soil leachates. Therefore, upon different freeze-thaw disturbance, the DOM content and bioavailability of soil leachates with low moisture tended to increase, particularly in the WBF soil leachates, which may result in an increased lea-ching of DOM in temperate forest soils during spring freeze-thaw periods. The results provide a refe-rence for further investigating DOM turnover in temperate forest soils during spring freeze-thaw periods.

KONG Yu-hua, ZHU Long-fei, WU Hao-hao, FU Ping-qing, XU Xing-kai. Effects of freeze-thaw and soil moisture on content and spectral structure properties of dissolved organic matter in forest soil leachates.[J]. Chinese Journal of Applied Ecology, 2019, 30(9): 2903-2914.

References

[1] Sun H (孙辉), Qin J-H (秦纪洪), Wu Y (吴杨). Freeze-thaw cycles and their impacts on ecological process: A review. Soils (土壤), 2008, 40(4): 505-509 (in Chinese)
[2] Kreyling J, Beierkuhnlein C, Pritsch K, et al. Recurrent soil freeze-thaw cycles enhance grassland producti-vity. New Phytologist, 2008, 177: 938-945
[3] Wu X (伍星), Shen Z-Y (沈珍瑶). Effects of freezing-thawing cycle on greenhouse gases production and emission from soil: A review. Chinese Journal of Ecology (生态学杂志), 2010, 29(7): 1432-1439 (in Chinese)
[4] Wang J-Y (王娇月), Song C-C (宋长春), Wang X-W (王宪伟), et al. Progress in the study of effect of freeze-thaw processes on the organic carbon pool and microorganisms in soils. Journal of Glaciology and Geocryology (冰川冻土), 2011, 33(2): 442-452 (in Chinese)
[5] Nikrad MP, Kerkhof LJ, Häggblom MM. The subzero microbiome: Microbial activity in frozen and thawing soils. FEMS Microbiology Ecology, 2016, 92, doi: 10.1093/femsec/fiw081
[6] Nebbioso A, Piccolo A. Molecular characterization of dissolved organic matter (DOM): A critical review. Analytical and Bioanalytical Chemistry, 2013, 405: 109-124
[7] Li S-D (李帅东), Jiang Q-L (姜泉良), Li Y (黎烨), et al. Spectroscopic characteristics and sources of dissolved organic matter from soils around Dianchi Lake, Kunming. Spectroscopy and Spectral Analysis (光谱学与光谱分析), 2017, 37(5): 1448-1454 (in Chinese)
[8] Zi Y-Y (訾园园), Kong F-L (孔范龙), Xi M (郗敏), et al. Three dimensional fluorescent characteristics of soil dissolved organic matter (DOM) in Jiaozhou Bay coastal wetlands, China. Chinese Journal of Applied Ecology (应用生态学报), 2016, 27(12): 3871-3881 (in Chinese)
[9] Hentschel K, Borken W, Matzner E. Repeated freeze-thaw events affect leaching losses of nitrogen and dissolved organic matter in a forest soil. Journal of Plant Nutrition and Soil Science, 2008, 171: 699-706
[10] Campbell JL, Reinmann AB, Templer PH. Soil freezing effects on sources of nitrogen and carbon leached during snowmelt. Soil Science Society of America Journal, 2014, 78: 297-308
[11] Haei M, quist MG, Ilstedt U, et al. The influence of soil frost on the quality of dissolved organic carbon in a boreal forest soil: Combining field and laboratory experiments. Biogeochemistry, 2012, 107: 95-106
[12] Xue S (薛爽), Wang Q (王茜), Qiu F-G (仇付国), et al. Effect of freezing-thawing on the spectroscopic characteristics of dissolved organic matter in soil. Acta Scientiae Circumstantiae (环境科学学报), 2016, 36(5): 1824-1832 (in Chinese)
[13] Fuss CB, Driscoll CT, Groffman PM, et al. Nitrate and dissolved organic carbon mobilization in response to soil freezing variability. Biogeochemistry, 2016, 131: 35-47
[14] Miao M (苗敏), Wu H-H (吴浩浩), Han L (韩琳), et al. Concentrations and components of dissolved organic matter and its spectral characteristics in soil leachates from a temperate forest stand. Environmental Science & Technology (环境科学与技术), 2018, 41(12): 169-178 (in Chinese)
[15] Franzluebbers AJ. Microbial activity in response to water-filled pore space of variably eroded southern Piedmont soils. Applied Soil Ecology, 1999, 11: 91-101
[16] McKnight DM, Boyer EW, Westerhoff PK, et al. Spectrofluorometric characterization of dissolved organic matter for indication of precursor organic material and aromaticity. Limnology and Oceanography, 2001, 46: 38-48
[17] Weishaar JL, Aiken GR, Bergamaschi BA, et al. Eva-luation of specific ultraviolet absorbance as an indicator of the chemical composition and reactivity of dissolved organic carbon. Environmental Science and Technology, 2003, 37: 4702-4708
[18] Cory RM, Miller MP, McKnight DM, et al. Effect of instrument-specific response on the analysis of fulvic acid fluorescence spectra. Limnology and Oceanography, 2010, 8: 67-78
[19] Zsolnay A, Baigar E, Jimenez M, et al. Differentiating with fluorescence spectroscopy the sources of dissolved organic matter in soils subjected to drying. Chemosphere, 1999, 38: 45-50
[20] Huguet A, Vacher L, Relexans S, et al. Properties of fluorescent dissolved organic matter in the Gironde Estuary. Organic Geochemistry, 2009, 40: 706-719
[21] Vignudelli S, Santinelli C, Murru E, et al. Distributions of dissolved organic carbon (DOC) and chromophoric dissolved organic matter (CDOM) in coastal waters of the northern Tyrrhenian Sea (Italy). Estuarine, Coastal & Shelf Science, 2004, 60: 133-149
[22] Wu HH, Xu XK, Cheng WG, et al. Antecedent soil moisture prior to freezing can affect quantity, composition and stability of soil dissolved organic matter during thaw. Scientific Reports, 2017, 7: 6380, doi:10.1038/s41598-017-06563-8
[23] Murphy KR, Stedmon CA, Graeber D, et al. Fluorescence spectroscopy and multi-way techniques: PARAFAC. Analytical Methods, 2013, 5: 6557-6566
[24] Chen W, Westerhoff P, Leenheer JA, et al. Fluorescence excitation-emission matrix regional integration to quantify spectra for dissolved organic matter. Environmental Science and Technology, 2003, 37: 5701-5710
[25] Han L (韩露), Wan Z-M (万忠梅), Sun H-Y (孙赫阳). Research progress on the effects of freezing and thawing on soil physical, chemical and biological properties. Chinese Journal of Soil Science (土壤通报), 2018, 49(3): 736-742 (in Chinese)
[26] Zheng X-B (郑兴波), Zhang X (张雪), Han S-J (韩士杰). Changes of soil aggregate size composition and origin canbon content at different succession stages of broad-leaved Korean pine forest in Changbai Mountain, China. Chinese Journal of Applied Ecology (应用生态学报), 2019, 30(5): 1553-1562 (in Chinese)
[27] Patel KF, Corianne T, Macrae JD, et al. Soil carbon and nitrogen responses to snow removal and concrete frost in a northern coniferous forest. Canadian Journal of Soil Science, 2018, 98: 436-447
[28] Jia G-J (贾国晶), Zhou Y-B (周永斌), Dai L-M (代力民), et al. Effect of freezing-thawing on e carbon and nitrogen mineralization in Changbai Mountain. Ecology and Environmental Sciences (生态环境学报), 2012, 21(4): 624-628 (in Chinese)
[29] Tan B, Wu FZ, Yang WQ, et al. Snow removal alters soil microbial biomass and enzyme activity in a Tibetan alpine forest. Applied Soil Ecology, 2014, 76: 34-41
[30] Yang Z, Gao J, Yang M, et al. Effects of freezing intensity on soil solution nitrogen and microbial biomass nitrogen in an alpine grassland ecosystem on the Tibetan Plateau, China. Journal of Arid Land, 2016, 8: 749-759
[31] Yuan X-C (元晓春), Lin W-S (林伟盛), Pu X-T (蒲晓婷), et al. Effects of forest regeneration patterns on the quantity and chemical structure of soil solution dissolved organic matter in a subtropical forest. Chinese Journal of Applied Ecology (应用生态学报), 2016, 27(6): 1845-1852 (in Chinese)
[32] Zhu L-F (朱龙飞). Effect of Freeze-thaw Disturbance on Soil GHG fluxes and Characteristics of DOM in Temperate Forest Soil Leachate. Master Thesis. Zhengzhou: Henan Agricultural University, 2019 (in Chinese)