Regulation of warming on the mixed decomposition of Artemisia ordosica and Leymus secalinus litter in Mu Us Desert, China is time-dependent

doi:10.13287/j.1001-9332.202407.001

Abstract

Abstract: Warming drives material cycling in terrestrial ecosystems by affecting litter decomposition, as it can alter litter yield, quality and decomposer composition and activity. The effect of warming on the decomposition of mixed litter in arid and semi-arid zones remains unknown. We investigated the mass loss and nutrient release dynamics during 450 days of decomposition of Artemisia ordosica, Leymus secalinus, and their mixture in Mu Us Desert by open-top chambers and litter bags. The results showed interspecific differences in the responses to warming, in that warming promoted mass loss and N and P release from L. secalinus and inhibited mass loss and P but promoting N release from A. ordosica. Mixing of A. ordosica and L. secalinus litter inhibited decomposition. Warming enhanced the antagonistic effects of mixed decomposition. The total mass loss of mixed litter was decreased by 9%, and the release of N and P was decreased by 4.9% and 12.6%, respectively. The antagonistic effects of mixed litter mass loss and P release under the warming treatment gradually strengthened with time, with N release changing from a synergistic to an antagonistic effect at 150 d. The non-additive effects produced by the mixed decomposition of A. ordosica and L. secalinus litter were jointly regulated by temperature and time. Future research on mixed litter decomposition should consider the interaction between temperature and time.

Key words: warming, mixing, litter, non-additive effect

LUO Kai, JIA Xin, MU Yanmei, GAO Shengjie, HAO Shao-rong, ZHA Tianshan. Regulation of warming on the mixed decomposition of Artemisia ordosica and Leymus secalinus litter in Mu Us Desert, China is time-dependent[J]. Chinese Journal of Applied Ecology, 2024, 35(7): 1753-1761.

References

[1] Bradford MA, Veen GF, Bonis A. A test of the hierarchical model of litter decomposition. Nature Ecology & Evolution, 2017, 12: 1836-1845
[2] 王行, 闫鹏飞, 展鹏飞, 等. 植物质量、模拟增温及生境对凋落物分解的相对贡献. 应用生态学报, 2018, 29(2): 474-482
[3] Gong SW, Guo R, Zhang T, et al. Warming and nitrogen addition increase litter decomposition in a temperate meadow ecosystem. PLoS One, 2015, 10(3): e011-6013
[4] 蔡肖凌, 杨光蓉, 冯莹, 等. 食碎屑动物通过摄食更多高质量的凋落物促进混合分解效应. 应用生态学报, 2024, 35(2): 501-506
[5] Háttenschwiler S, Tiunov A, Scheu S, et al. Biodiversity and litter decomposition in terrestrial ecosystems. Annual Review of Ecology, Evolution, and Systematics, 2005, 36: 191-218
[6] Chen YC, Ma SQ, Jiang HM, et al. Decomposition time, chemical traits and climatic factors determine litter-mixing effects on decomposition in an alpine steppe ecosystem in Northern Tibet. Plant and Soil, 2021, 459: 23-35
[7] Wu DD, Li TT, Wang SQ. Time and litter species composition affect litter-mixing effects on decomposition rates. Plant and Soil, 2013, 371: 355-366
[8] 陈玥希, 陈蓓, 孙辉, 等. 川西高海拔增温和加氮对红杉凋落物有机组分释放的影响. 应用生态学报, 2017, 28(6): 1753-1760
[9] Schuster M, Kreyling J, Berwaers SG, et al. Drought inhibits synergistic interactions of native and exotic litter mixtures during decomposition in temperate grasslands. Plant and Soil, 2017, 415: 257-268
[10] 牟钰, 贾昕, 郑甲佳, 等. 毛乌素沙地油蒿枯落物分解对增温的响应. 北京林业大学学报, 2020, 42(6): 134-141
[11] Zhang XH, Sun XX, Mao R. Effects of litter evenness, nitrogen enrichment and temperature on short-term litter decomposition in freshwater marshes of Northeast China. Wetlands, 2017, 37: 145-152
[12] Jia X, Zha TS, Gong JN, et al. Carbon and water exchange over a temperate semi-arid shrubland during three years of contrasting precipitation and soil moisture patterns. Agricultural and Forest Meteorology, 2016, 228: 120-129
[13] Miao C, Bai YX, Zhang YQ, et al. Interspecific interactions alter plant functional strategies in a revegetated shrub-dominated community in the Mu Us Desert, China. Annals of Botany, 2022, 130: 149-158
[14] Mu YM, Yuan Y, Jia X, et al. Hydrological losses and soil moisture carryover affected the relationship between evapotranspiration and rainfall in a temperate semiarid shrubland. Agricultural and Forest Meteorology, 2022, 315: 108831
[15] 张建玲, 于明含, 孙慧媛, 等. 毛乌素沙地不同龄级黑沙蒿(Artemisia ordosica)枝叶功能性状对干旱的响应. 中国沙漠, 2024(2): 1-9
[16] Olson JS. Energy storage and the balance of producers and decomposers in ecological systems. Ecology, 1963, 44: 322-331
[17] Wang LF, Chen YM, Zhou Y, et al. Litter chemical traits strongly drove the carbon fractions loss during decomposition across an alpine treeline ecotone. Science of the Total Environment, 2021, 753: 142287
[18] 武启骞, 王传宽. 季节性雪被变化对森林凋落物分解及土壤氮动态的影响. 应用生态学报, 2018, 29(7): 2422-2432
[19] Yang S, Yao F, Ye J, et al. Latitudinal pattern of soil lignin/cellulose content and the activity of their degra-ding enzymes across a temperate forest ecosystem. Ecolo-gical Indicators, 2019, 102: 557-568
[20] Liu JX, Liu SG, Li YY, et al. Warming effects on the decomposition of two litter species in model subtropical forests. Plant and Soil, 2017, 420: 277-287
[21] Garcia-Palacios P, Maestre FT, Kattge J, et al. Climate and litter quality differently modulate the effects of soil fauna on litter decomposition across biomes. Ecology Letters, 2013, 16: 1045-1053
[22] Li AG, Fan YX, Chen SL, et al. Soil warming did not enhance leaf litter decomposition in two subtropical forests. Soil Biology and Biochemistry, 2022, 170: 108716
[23] 杨德春, 胡雷, 宋小艳, 等. 降雨变化对高寒草甸不同植物功能群凋落物质量及其分解的影响. 植物生态学报, 2021, 45(12): 1314-1328
[24] Spohn M, Berg B. Import and release of nutrients during the first five years of plant litter decomposition. Soil Biology and Biochemistry, 2023, 176: 108878
[25] Pérez-Suárez M, Arredondo-Moreno J, Huber-Sannwald E, et al. Early stage of single and mixed leaf-litter decomposition in semiarid forest pine-oak: The role of rainfall and microsite. Biogeochemistry, 2012, 108: 245-258
[26] Parton M, Silver WL, Burke I, et al. Global-scale similarities in nitrogen release patterns during long-term decomposition. Science, 2007, 315: 361-364
[27] Steinwandter M, Schlick-Steiner BC, Steiner F, et al. One plus one is greater than two: Mixing litter types accelerates decomposition of low-quality alpine dwarf shrub litter. Plant and Soil, 2019, 438: 405-419
[28] Cuchietti A, Marcotti E, Gurvich DE, et al. Leaf litter mixtures and neighbour effects: Low-nitrogen and high-lignin species increase decomposition rate of high-nitrogen and low-lignin neighbours. Applied Soil Ecology, 2014, 82: 44-51
[29] Hobbie SE. Plant species effects on nutrient cycling: Revisiting litter feedbacks. Trends in Ecology & Evolution, 2015, 30: 357-363
[30] Santonja M, Fernandez C, Gauquelin T, et al. Climate change effects on litter decomposition: Intensive drought leads to a strong decrease of litter mixture interactions. Plant and Soil, 2015, 393: 69-82
[31] Li H, Wu FZ, Yang WQ, et al. Effects of forest gaps on litter lignin and cellulose dynamics vary seasonally in an alpine forest. Forests, 2016, 7: 27
[32] Liu XF, Chen SD, Li XJ, et al. Soil warming delays leaf litter decomposition but exerts no effect on litter nutrient release in a subtropical natural forest over 450 days. Geoderma, 2022, 427: 116139
[33] Yang K, Shi W, Zhu JJ. The impact of secondary forests conversion into larch plantations on soil chemical and microbiological properties. Plant and Soil, 2013, 368: 535-546
[34] Vos V, Van Ruijven J, Berg M, et al. Leaf litter quality drives litter mixing effects through complementary resource use among detritivores. Oecologia, 2013, 173: 269-280
[35] Butenschoen O, Krashevska V, Maraun M, et al. Litter mixture effects on decomposition in tropical montane rainforests vary strongly with time and turn negative at later stages of decay. Soil Biology & Biochemistry, 2014, 77: 121-128
[36] Joly F, Milcu A, Scherer-Lorenzen M, et al. Tree species diversity affects decomposition through modified micro-environmental conditions across European forests. New Phytologist, 2017, 214: 1287-1293