Changes of soil nutrients and organic carbon fractions in Caragana korshinskii forests with different restoration years in mountainous areas of southern Ningxia, China

doi:10.13287/j.1001-9332.202403.018

Abstract

Abstract: Vegetation restoration can effectively enhance soil quality and soil organic carbon (SOC) sequestration. In this study, the distribution characteristics of soil nutrients and SOC along soil profile (0-100 cm), and their responses to restoration years (16, 28, 38 years) were studied in Caragana korshinskii plantations in the southern mountainous area of Ningxia, compared with cropland and natural grassland. The results showed that: 1) the contents of SOC, soil total nitrogen (TN), total phosphorus (TP), particulate organic carbon (POC), mineral-associated organic carbon (MAOC) and the proportion of particulate organic carbon to total organic carbon (POC/SOC) all decreased with increasing soil depth. The ratio of mineral-associated organic carbon to total organic carbon (MAOC/SOC) exhibited an opposite trend. 2) The contents of SOC, TN, TP, C:P, N:P, POC and MAOC gra-dually decreased as the restoration years increased. However, the C:N ratio showed no significant change. The POC/SOC ratio initially increased and then decreased, while the MAOC/SOC ratio decreased initially and then increased. 3) In three different types of vegetation, POC, MAOC, and SOC showed a highly significant positive linear correlation, with the increase in SOC mainly depended on the increase in MAOC. The SOC, TN, TP, POC and MAOC contents in natural grassland and C. korshinskii plantations were significantly higher than those in cropland. In conclusion, soil nutrients and POC and MAOC contents of C. korshinskii plantations gradually decreased with the increases in restoration years. However, when compared with cropland, natural grassland and C. korshinskii plantations demonstrated a greater capacity to maintain and enhance soil nutrient and carbon storage.

Key words: vegetation restoration, restoration years, soil profile, soil organic carbon component, mountainous areas of southern Ningxia

ZHANG Yuhan, LI Yao, ZHOU Yue, CHEN Yuanjia, AN Shaoshan. Changes of soil nutrients and organic carbon fractions in Caragana korshinskii forests with different restoration years in mountainous areas of southern Ningxia, China[J]. Chinese Journal of Applied Ecology, 2024, 35(3): 639-647.

References

[1] Sokol NW, Bradford MA. Microbial formation of stable soil carbon is more efficient from belowground than aboveground input. Nature Geoscience, 2019, 12: 46-53
[2] Lal R. Soil carbon sequestration impacts on global climate change and food security. Science, 2004, 304: 1623-1627
[3] Cotrufo MF, Ranalli MG, Haddix ML, et al. Soil carbon storage informed by particulate and mineral-associated organic matter. Nature Geoscience, 2019, 12: 989-994
[4] Rocci KS, Lavallee JM, Stewart CE, et al. Soil organic carbon response to global environmental change depends on its distribution between mineral-associated and particulate organic matter: A meta-analysis. Science of the Total Environment, 2021, 793: 148569
[5] 王楚涵, 刘菲, 高健永, 等. 减氮覆膜下土壤有机碳组分含量的变化特征. 中国农业科学, 2022, 55(19): 3779-3790
[6] Li CZ, Zhao LH, Sun PS, et al. Deep soil C, N, and P stocks and stoichiometry in response to land use patterns in the loess hilly region of China. PLoS One, 2016, 11: e0159075
[7] 郭文芳, 李鑫, 陈艳梅, 等. 太行山坡地不同管理措施植被-土壤系统耦合关系. 生态学报, 2023, 43(15): 6170-6181
[8] 雷少刚, 王维忠, 李园园, 等. 北方大型露天矿区土壤有机碳库扰动与恢复研究. 煤炭科学技术, 2023, 51(12): 100-109
[9] 田昕, 赵勇钢, 刘啟霞, 等. 黄土丘陵区长期种植柠条坡地土壤饱和导水率及其影响因素. 中国水土保持科学, 2023, 21(4): 20-27
[10] 张国平. 半干旱地区柠条造林技术. 现代园艺, 2022, 45(18): 34-36
[11] 闫佳兴, 石文凯, 韩海荣, 等. 晋北黄土丘陵沟壑区柠条锦鸡儿叶功能性状特征及环境响应. 生态学杂志, 2023, 42(7): 1595-1603
[12] 王永强, 吕雯, 马晓梅, 等. 宁南带状柠条林地根系及土壤水分养分分布特征. 西北林学院学报, 2023, 38(1): 42-49
[13] 鲍士旦. 土壤农化分析. 第三版. 北京: 中国农业出版社, 2008: 34-35
[14] Sokol NW, Kuebbing SE, Karlsen-Ayala E, et al. Evidence for the primacy of living root inputs, not root or shoot litter, in forming soil organic carbon. New Phytologist, 2019, 221: 233-246
[15] 王燕, 武兴宝, 秦新惠, 等. 荒漠绿洲农田盐渍化过程中的土壤碳、氮、磷生态化学计量特征. 新疆农业科学, 2023, 60(8): 1996-2005
[16] 文丽, 李超, 程凯凯, 等. 不同农田模式下土壤有机碳、氮、磷及化学计量比的垂直分布特征. 湖南农业科学, 2023(2): 38-42
[17] Castellano MJ, Mueller KE, Olk DC, et al. Integrating plant litter quality, soil organic matter stabilization, and the carbon saturation concept. Global Change Biology, 2015, 21: 3200-3209
[18] Angst G, Mueller KE, Castellano MJ, et al. Unlocking complex soil systems as carbon sinks: Multi-pool management as the key. Nature Communications, 2023, 14: 2967
[19] 姚忠凯. 玉米秸秆和生物炭添加对颗粒态、矿物结合态有机碳激发效应的影响. 博士论文. 重庆: 重庆三峡学院, 2023
[20] Xiao KQ, Zhao Y, Liang C, et al. Introducing the soil mineral carbon pump. Nature Reviews Earth & Environment, 2023, 4: 135-136
[21] Golchin A, Oades J, Skjemstad J, et al. Study of free and occluded particulate organic matter in soils by solid state ¹³C CP/MAS NMR spectroscopy and scanning electron microscopy. Soil Research, 1994, 32: 285-309
[22] Loranger-Merciris G, Barthes L, Gastine A, et al. Rapid effects of plant species diversity and identity on soil microbial communities in experimental grassland ecosystems. Soil Biology and Biochemistry, 2006, 38: 2336-2343
[23] 秦树高. 柠条林草带状复合系统地下竞争关系研究. 博士论文. 北京: 北京林业大学, 2011
[24] 梁燊, 刘亚斌, 石川等. 黄土区不同龄期灌木柠条锦鸡儿根系的分布特征及其固土护坡效果. 农业工程学报, 2023, 39(15): 114-124
[25] 王国华, 宋冰, 席璐璐, 等. 晋西北丘陵风沙区不同林龄人工柠条生长与繁殖动态特征. 应用生态学报, 2021, 32(6): 2079-2088
[26] 王子寅, 刘秉儒, 李子豪, 等. 不同发育阶段柠条灌丛堆土壤生态化学计量学特征. 中国草地学报, 2023, 45(5): 9-19
[27] Cleveland C, Liptzin D. C:N:P stoichiometry in soil: Is there a “Redfield ratio” for the microbial biomass? Biogeochemistry, 2007, 85: 235-252
[28] Hütsch BW, Augustin J, Merbach W. Plant rhizodeposition: An important source for carbon turnover in soils. Journal of Plant Nutrition and Soil Science, 2002, 165: 397-407
[29] 何亚婷, 何友均, 王鹏, 等. 不同经营模式对蒙古栎林土壤有机碳组分的长效性影响. 生态环境学报, 2023, 32(1): 11-17
[30] Villarino SH, Pinto P, Jackson RB, et al. Plant rhizodeposition: A key factor for soil organic matter formation in stable fractions. Science Advances, 2021, 7: eabd3176
[31] 樊廷录, 王淑英, 周广业, 等. 长期施肥下黑垆土有机碳变化特征及碳库组分差异. 中国农业科学, 2013, 46(2): 300-309
[32] Chao L, Schimel JP, Jastrow JD. The importance of anabolism in microbial control over soil carbon storage. Nature Microbiology, 2017, 2: 17105
[33] Liu FT, Qin SQ, Fang K, et al. Divergent changes in particulate and mineral-associated organic carbon upon permafrost thaw. Nature Communications, 2022, 13: 5073
[34] Dungait J, Hopkins D, Gregory A, et al. Soil organic matter turnover is governed by accessibility not recalcitrance. Global Change Biology, 2012, 18: 1781-1796
[35] Bradford MA, Keiser AD, Davies CA, et al. Empirical evidence that soil carbon formation from plant inputs is positively related to microbial growth. Biogeochemistry, 2013, 113: 271-281
[36] Clemmensen KE, Bahr A, Ovaskainen O, et al. Roots and associated fungi drive long-term carbon sequestration in boreal forest. Science, 2013, 339: 1615-1618
[37] Ren C, Zhao F, Kang D, et al. Linkages of C:N:P stoichiometry and bacterial community in soil following afforestation of former farmland. Forest Ecology and Management, 2016, 376: 59-66
[38] 杨娥女. 黄土高原不同生态系统土壤有机碳特征和稳定性研究. 硕士论文. 杨凌: 西北农林科技大学, 2022
[39] 张琪琳, 王占礼, 王栋栋, 等. 黄土高原草地植被对土壤侵蚀影响研究进展. 地球科学进展, 2017, 32(10): 1093-1101
[40] Lavallee JM, Soong JL, Cotrufo MF. Conceptualizing soil organic matter into particulate and mineral-associated forms to address global change in the 21st century. Global Change Biology, 2020, 26: 261-273
[41] 梁尧, 韩晓增, 王凤菊, 等. 草地和农田生态系统中黑土活性有机碳的特征. 土壤通报, 2011, 42(4): 864-871