Investigating litter production of shrub and grass species in semi-arid rangeland using structural equation model

Document Type : Research Paper

Authors

1 Associate Professor, Department of Ecological Engineering, Faculty of Natural Resources, University of Jiroft, Jiroft, Iran

2 Associate Professor, Departments of Range and Watershed Management, Faculty of Agriculture, Fasa University, Fasa, Iran

Abstract

Litter is the main source of energy which provides nutrients as absorbable form for vegetation. The reaction of plant species to the amount of litter is different. This study aimed to measure litter production and soil carbon of four species (Artemisa aucheri Boiss, Astergalus gossipinus fisch, Stipa barbata Desf. and Hyparrhenia hirta(L.) Stapf) under litter treatments (Removing and adding). Four litter treatments (0%, 50 %, 100% and 200% litter) were applied in 20 plots for each species, and then plots are marked. Litter quantity, litter qualify and soil carbon and moisture were measure in fall season. Four species are significantly different in terms of the litter quantity and qualify. Response of litter production of four species to add and remove litter was different. For all three species, soil carbon were significantly reduced with the removal of litter and increased significantly with the increase of litter (p<0.05). Structural equation model indicated that litter removal was the most important driver of litter production directly (p<0.01). Litter removal had a significant effect on litter production indirectly through the effect on soil moisture (P<0.05). The addition of litter also had a significant effect on litter production indirectly through the effect on soil carbon (p<0.05). The findings of this study indicate the importance of maintaining litter (at least 50 %) for the next year's litter production of plants, which should be considered in the sustainable management of rangelands.

Keywords

Main Subjects

References

Abubakar, A., Mayer, M., Neumann, M., Gao, Q., and Wang, D. 2025. Nitrogen addition reduces litter decomposition but does not affect litter production and chemistry in an alpine shrubland. Plant Soil. 509, 795–807.
Amatangelo, K.L., Dukes, J.S., and Field, C.B. 2008. Responses of a California annual grassland to litter manipulation. Journal of Vegetation Science. 19, 605-612.
Areejit, S., and Martin, O.C. 2013. Shining fresh light on the evolution of photosynthesis. Elife. 2, 01403.
Cadish, G., and Giller, K.E. 1997. Driven by nature, plant litter quality and decomposition. Wallingford, CAB International.
Campanella, M., and Bertiller, M.B. 2008. Plant phenology, leaf traits and leaf litterfall of contrasting life forms in the arid Patagonian Monte, Argentina. Journal of Vegetation Science. 19, 75–85.
Chapin III, F.S., Zavaleta, E.S., Eviner, V.T., Naylor, R.L.,  and Vitousek, P.M. 2000. Consequences of changing biodiversity. Nature. 405, 234–242.
Chen, W., Huang, D., Liu, N., Zhang, Y., Badgery, W.B., Wang, X., and Shen, Y. 2015. Improved grazing management may increase soil carbon sequestration in temperate steppe. Sci. Rep. 5, 10892.
Cheng, W., Tie, L., Zhou, S., Hu, J., Ouyang, S., and Huang, C. 2023. Effects of soil arthropods on non-Leaf Litter decomposition, A Meta-Analysis. Forests. 14(8), 1557. https://doi.org/10.3390/f14081557
da Silva, J.P., da Silva Teixeira, R., da Silva, I.R., Soares, E.M.B., and Lima, A.M.N. 2022. Decomposition and nutrient release from legume and non-legume residues in a tropical soil. Soil Science. 73, e13151.
Facelli, J.M., and Pickett, S.T.A. 1991. Plant litter, light interception and effects on an old-Field plant community. Ecology. 72, 1024-1031.
Ganjurjav, H., Hu, G., Wan, Y., Li, Y., Danjiu, L., and Gao, Q. 2018. Different responses of ecosystem carbon exchange to warming in three types of alpine grassland on the central Qinghai-Tibetan Plateau. Ecology and Evolution. 8 (3), 1507-1520.
Giebelmann, U.C., Martins, K.G., Brandle, M., Schadler, M., Marques, R., and Brandl, R. 2013. Lack of home-field advantage in the decomposition of leaf litter in the Atlantic rainforest of Brazil. Applied Soil Ecology. 8,1.
Giweta, M. 2020. Role of litter production and its decomposition, and factors affecting the processes in a tropical forest ecosystem, a review. Journal of Ecology and Environment. 44, 11.
Grau-Andrés, R., Wardle, D.A., and Kardol, P. 2022. Bryosphere loss impairs litter decomposition consistently across moss species, litter types, and micro-Arthropod abundance. Ecosystems. 25, 1542–1554.
Hadi, A., Naz, N., Rehman, F.U., Kalsoom, M., Tahir, R., Adnan, M., Saeed, M.S., Khan, A.H., and Mehta, J. 2020. Impact of climate change drivers on C4 plants; A review. Current Research in Agriculture and Farming. 1, 13-18.
Hassan, N., Sher, Kh., Rab, A., Abdullah, I., Zeb, U., Naeem, I., Shuaib, M., Khan, H., Khan, W., and Khan, A. 2021. Effects and mechanism of plant litter on grassland ecosystem: A review. Acta Ecologica Sinica. 41, 341-345.
Hou, S.L., Hättenschwiler, S., Yang, J.J., Sistla, S., Wei, H.W., Zhang, Z.W., Hu, Y.Y., Wang, R.Z., Cui, S.Y., Lü, X.T. and Han, X.G., 2021. Increasing rates of long-term nitrogen deposition consistently increased litter decomposition in a semi-arid grassland. New Phytologist. 229, 296-307.
Jiang, W., Wu, H., Li, Q., Lin, Y., and Yu, Y. 2019. Spatiotemporal changes in C4 plant abundance in China since the Last Glacial Maximum and their driving factors. Palaeogeography, Palaeoclimatology, Palaeoecology. 518, 10-21.
Kamruzzaman, Md., Basak, K., Paul, S. K., Ahmed, S., and Osawa, A. 2019. Litterfall production, decomposition and nutrient accumulation in Sundarbans mangrove forests, Bangladesh. Forest Science and Technology. 15(1), 24–32.
Langlois, J., Guilhaumon, F., Bockel, Th., Boissery, P., Braga, C.D.A., Deter, J., Holon, F., Marre, G., Tribot, A.S., and Mouquet, N. 2021. An integrated approach to estimate aesthetic and ecological values of coralligenous reefs. Ecological Indicators. 129, 107935.
Li, J., Yang, C., Zhou, H., and Shao, X. 2020. Responses of plant diversity and soil microorganism diversity to water and nitrogen additions in the Qinghai-Tibetan Plateau. Global Ecology and Conservation. 22, e01003.
Li, M., Wan, Sh., Colin, Ch., Jin, H., Zhao, D., Pei, W., Jiao, W., Tang, Y., Tan, Y., Shi, X., and Li, A. 2023. Expansion of C4 plants in South China and evolution of East Asian monsoon since 35 Ma, Black carbon records in the northern South China Sea. Global and Planetary Change. 223, 104079.
Li, P., Sayer, E.J., Jia, Z., Liu, W., Wu, Y., Yang, S., Wang, C., Yang, L.u., Chen, D., Bai, Y., and Liu, L. 2020. Deepened winter snow cover enhances net ecosystem exchange and stabilizes plant community composition and productivity in a temperate grassland. Global Change Biology. 26 (5), 3015-3027.
Lin, G., and Zeng, D.H. 2018.Functional identity rather than functional diversity or species richness controls litter mixture decomposition in a subtropical forest. Plant and Soil. 428, 179-193.
Liu L. 2012. Patterns of litterfall and nutrient return at different altitudes in evergreen hardwood forests of Central Taiwan. Annals of Forest Science. 69(8), 877–86.
Liu, D., Li, Y., Wang, T., Peylin, P., MacBean, N., Ciais, G., Jia, P., Ma, M., Ma, Y., Shen, M., Zhang, X. and Piao, S. 2018. Contrasting responses of grassland water and carbon exchanges to climate change between Tibetan Plateau and Inner Mongolia. Agricultural and Forest Meteorology. 249, 163-175.
Liu, X., Zhu, D., Zhan, W., Chen, H., Zhu, Q., Hao, Y., Liu, W., and He, Y. 2019. Five-year measurements of net ecosystem CO2 exchange at a fen in the Zoige peatlands on the Qinghai-Tibetan Plateau. Journal of Geophysical Research: Atmospheres. 24 (22), 11803-11818.
Ma, L., Guo, C., Xin, X., Yuan, S., and Wang, R. 2013. Effects of belowground litter addition, increased precipitation and clipping on soil carbon and nitrogen mineralization in a temperate steppe. Biogeosciences. 10.
MacDicken, K.G. 1997. A guide to monitoring carbon storage in forestry and agroforestry projects. Winrock Internationl Institute for Agricultural Development, Forest Carbon Monitoring Program.
Mohmedi Kartalaei, Z., Kooch, Y., and Dianati Tilaki, Gh.A. 2023. Litter and soil properties under woody and non-woody vegetation types, Implication for ecosystem management in a mountainous semi-arid landscape. Journal of Environmental Management. 348, 119238.
Nelson, D.W., and Sommers, L.E. 1982. Total carbon, organic carbon, organic matter. In, Page, A.L., Miller, R.H., Kenney, D.R. (Eds.(, Methods of Soil Analysis, Part 1, 2nd Edition. Agronomy Monograph 9. American Society of Agronomy, Madison, Wisconsin, USA, pp. 539–580.
Ogée, J., Lamaud, E., Brunet, Y., Berbigier, P., and Bonnefond, J.M. 2001. A long-term study of soil heat flux under a forest canopy. Agriculture and Forest Meteorology. 106, 173-187.
Pang, Y., Tian, J., Liu, L.X., Han, L.N., and Wang, D.X. 2021. Coupling of different plant functional group, soil, and litter nutrients in a natural secondary mixed forest in the Qinling Mountains, Environmental Science and Pollution Research. 28, 66272-66286.
Porqueddu, C., Ates, S., Louhaichi, M., Kyriazopoulos, A.P., Moreno, G., Pozo, A.d., Ovalle, C., Ewing, M.A., and Nichols, P.G.H. 2016. Grasslands in 'Old World' and 'New World' Mediterranean-climate zones, past trends, current status and future research priorities. Grass and Forage Science. 71, 1-35.
Porre, R.J., van der Werf, W., De Deyn G.B., Stomph, T.J., and Hoffland, H. 2020. Is litter decomposition enhanced in species mixtures? A meta-analysis. Soil Biology and Biochemistry. 145, 107791.
Shen, Y., Chen, Y.W.,  Yang, G., Yang, X., Liu, N., Sun, X., Chen, J., and Zhang, Y. 2016. Can litter addition mediate plant productivity responses to increased precipitation an d nitrogen deposition in a typical steppe?. Ecological Research. 31. 
Suding, K., and Goldberg, D. 1999. Variation in the effects of vegetation and litter on recruitment across productivity gradients. Journal of Ecology. 87, 436–449.
Taylor, S.H., Ripley, B.S., Martin, T., De-Wet, L.A., Woodward, F., and Osborne, C.P. 2014. Physiological advantages of C4 grasses in the field: a comparative experiment demonstrating the importance of drought. Global Change Biology. 20, 1992–2003.
Triadiati, Tjitrosemito, S., Guhardja, E., Sudarsono, Qayim, I., and Leuschner, C. 2011. Litterfall Production and Leaf-litter Decomposition at Natural Forest and Cacao Agroforestry in Central Sulawesi, Indonesia. Asian Journal of Biological Sciences. 4, 221-234.
Vargas, D.N., Bertiller, M.B., Ares, J.O., Carrera, A.L., and Sain, C.L. 2006. Soil C and N dynamics induced by leaf-litter decomposition of shrubs and perennial grasses of the Patagonian Monte. Soil Biology and Biochemistry. 38, 2401–2410.
Veen, P., Jefferson, R., Smidt, J., and Straaten, J. 2009. Grasslands in Europe of high nature value. KNNV Publishing, Zeist, the Netherlands.
Violle, C., Richarte, J., and Navas, M.L. 2006. Effects of litter and standing biomass on growth and reproduction of two annual species in a Mediterranean old-field. J Ecol. 94, 196–205.
Vogan P.J., and Sage R.F. 2011. Water-use efficiency and nitrogen-use efficiency of C3–C4 intermediate species of Flaveria Juss. (Asteraceae). Plant, Cell and Environment. 34, 1415–1430.
Wang, D., He, H.L., Gao, Q., Zhao, C.Z., Zhao, W.Q., Yin, C.Y., Chen, X.L., Ma, Z.L., Li, D.D., and Sun, D.D. 2017. Effects of short-term N addition on plant biomass allocation and C and N pools of the Sibiraea angustata scrub ecosystem. Eur J Soil Sci. 68, 212–220.
Wang, Z., Yuan, X., Wang, D., Zhang, Y., Zhong, Z., Guo, Q., and Feng, C. 2018. Large herbivores influence plant litter decomposition by altering soil properties and plant quality in a meadow steppe. Scientific Reports. 8(1), 9089.
Weltzin, J.F., Keller, J.K., Bridgham, S.D., Pastor, J., Allen, P.B., and Chen, J. 2005. Litter controls plant community composition in a northern fen. Oikos. 110, 537-546.
Wieder, W.R., Cleveland, C.C., Taylor, Ph.G., Nemergut, D.R., Hinckley, E.L., Philippot, L., Weintraub, S.R., Martin, M., and Townsend, A.R. 2013. Experimental removal and addition of leaf litter inputs reduces nitrate production and loss in a lowland tropical forest. Biogeochemistry. 113, 629-642.
Wu, G.L., Liu, Y., Tian, F.P., and Shi, Zh.H. 2017. Legumes functional group promotes soil organic carbon and nitrogen storage by increasing plant diversity. Land Degradation and Development. 28, 1336-1344.
Xiong, S., and Nilsson, C., 1997. Dynamics of leaf litter accumulation and its effects on riparian vegetation: a review. Botanical Review. 63, 240–261.
You, Y., Wang, S., Pan, N., Ma, Y., and Liu, W. 2020. Growth stage-dependent responses of carbon fixation process of alpine grasslands to climate change over the Tibetan Plateau, China. Agricultural and Forest Meteorology. 291.
Zhang, W.P., Fornara, D., Yang, H., Yu, R.P., Callaway, R.M., and Li, L. 2023. Plant litter strengthens positive biodiversity–ecosystem functioning relationships over time. Trends in Ecology & Evolution. 38, 473-484.
Zhang, X., Heděnec, P., Yue, K., Ni, X., Wei, X., Chen, Z., Yang, J., and Wu, F. 2024. Global forest gaps reduce litterfall but increase litter carbon and phosphorus release. Communications Earth & Environment. 5, 288.
Zheng, X., Liu, Q., Zheng, L.Y., Wang, S.L., Huang, L.J., Jiang, J., Wang, B.H., Liu, X.J., Li, X.D., Hu, X.F., Guo, X.M., and Zhang, L. 2020. Litter removal enhances soil N2O emissions: Implications for management of leaf-harvesting Cinnamomum camphora plantations. Forest Ecology and Management. 466, 118121.
Zhou, Y., Pei, Z., Su, J., Zhang, J., Zheng, Y., Ni, J., Xiao, C., and Wang, R. 2012. Comparing Soil Organic Carbon Dynamics in Perennial Grasses and Shrubs in a Saline-Alkaline Arid Region, Northwestern China. PLoS ONE. 7(8), e42927.
Environmental Resources Research
Volume 13, Issue 1
July 2025
Pages 49-59

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