Ecosystem regime shifts and its application prospects to ecosystem management in cold and arid regions

doi:10.13287/j.1001-9332.202407.002

Abstract

Abstract: Ecosystem regime shifts refer to the drastically changes of an ecosystem from one state to another after suffering disturbances that exceed the thresholds. Although land desertification and grassland degradation, which are common in the cold and arid regions, are gradual processes, sudden changes can also occur when the duration or intensity of disturbances exceed the thresholds. Therefore, the study of ecosystem regime shifts is of great significance to the management of ecosystems in cold and arid regions. In this review, we summarized the evolution of ecosystem regime shift theory and early warning signals, and analyzed the problems of land desertification and grassland degradation in cold and arid regions, as well as potential responses of ecosystems to different stresses. We further put forward research frameworks for the evolution and mutation characteristics of the rain-fed artificial sand fixation system and alpine meadows. The future research needed to be strengthened in identifying the key drivers of ecosystem regime shifts at different stages, determining the corresponding thresholds, emphasizing the mechanism of water-limited mutation induced by extreme climatic events and its early warning, and promoting the application of regime shift research to ecosystem management in arid and arid regions.

Key words: ecosystem regime shift, land desertification, grassland degradation, artificial sand-fixing system, Kobresia meadow

WANG Yuxin, ZHAO Wenzhi, LIU Hu. Ecosystem regime shifts and its application prospects to ecosystem management in cold and arid regions[J]. Chinese Journal of Applied Ecology, 2024, 35(7): 1997-2005.

References

[1] Scheffer M, Carpenter S, Foley JA, et al. Catastrophic shifts in ecosystems. Nature, 2001, 413: 591-596
[2] Hastings A, Abbott KC, Cuddington K, et al. Transient phenomena in ecology. Science, 2018, 361: eaat6412
[3] Moreno-Fernandez D, Viana-Soto A, Camarero JJ, et al. Using spectral indices as early warning signals of forest dieback: The case of drought-prone Pinus pinaster forests. Science of the Total Environment, 2021, 793: 148578
[4] Berdugo M, Delgado-Baquerizo M, Soliveres S, et al. Global ecosystem thresholds driven by aridity. Science, 2020, 367: 787-790
[5] 徐兴良, 于贵瑞. 基于生态系统演变机理的生态系统脆弱性、适应性与突变理论. 应用生态学报, 2022, 33(3): 623-628
[6] Scheffer M, Bascompte J, Brock WA, et al. Early-war-ning signals for critical transitions. Nature, 2009, 461: 53-59
[7] Van Geest GJ, Coops H, Scheffer M, et al. Long transients near the ghost of a stable state in eutrophic shallow lakes with fluctuating water levels. Ecosystems, 2007, 10: 36-46
[8] Kéfi S, Holmgren M, Scheffer M. When can positive interactions cause alternative stable states in ecosystems? Functional Ecology, 2016, 30: 88-97
[9] Munson SM, Reed SC, Peñuelas J, et al. Ecosystem thresholds, tipping points, and critical transitions. New Phytologist, 2018, 218: 1315-1317
[10] Bestelmeyer BT, Ellison AM, Fraser WR, et al. Analysis of abrupt transitions in ecological systems. Ecosphere, 2011, 2: art129
[11] Sun GQ, Wang CH, Chang LL, et al. Effects of feedback regulation on vegetation patterns in semi-arid environments. Applied Mathematical Modelling, 2018, 61: 200-215
[12] Rietkerk M, Bastiaansen R, Banerjee S, et al. Evasion of tipping in complex systems through spatial pattern formation. Science, 2021, 374: eabj0359
[13] Hillebrand H, Donohue I, Harpole WS, et al. Thre-sholds for ecological responses to global change do not emerge from empirical data. Nature Ecology & Evolution, 2020, 4: 1502-1509
[14] Morozov A, Abbott K, Cuddington K, et al. Long transients in ecology: Theory and applications. Physics of Life Reviews, 2020, 32: 1-40
[15] Scheffer M, Carpenter SR. Catastrophic regime shifts in ecosystems: Linking theory to observation. Trends in Ecology & Evolution, 2003, 18: 648-656
[16] Kéfi S, Guttal V, Brock WA, et al. Early warning signals of ecological transitions: Methods for spatial patterns. PLoS One, 2014, 9(3): e92097
[17] Guttal V, Jayaprakash C. Changing skewness: An early warning signal of regime shifts in ecosystems. Ecology Letters, 2008, 11: 450-460
[18] Biggs R, Carpenter SR, Brock WA. Turning back from the brink: Detecting an impending regime shift in time to avert it. Proceedings of the National Academy of Sciences of the United States of America, 2009, 106: 826-831
[19] Carpenter SR, Brock WA. Rising variance: A leading indicator of ecological transition. Ecology Letters, 2006, 9: 311-318
[20] Dakos V, Scheffer M, Van Nes EH, et al. Slowing down as an early warning signal for abrupt climate change. Proceedings of the National Academy of Sciences of the United States of America, 2008, 105: 14308-14312
[21] Majumder S, Tamma K, Ramaswamy S, et al. Inferring critical thresholds of ecosystem transitions from spatial data. Ecology, 2019, 100: e02722
[22] Carpenter SR, Cole JJ, Pace ML, et al. Early warnings of regime shifts: A whole-ecosystem experiment. Science, 2011, 332: 1079-1082
[23] De Paoli H, Van Der Heide T, Van Den Berg A, et al. Behavioral self-organization underlies the resilience of a coastal ecosystem. Proceedings of the National Academy of Sciences of the United States of America, 2017, 114: 8035-8040
[24] Kéfi S, Rietkerk M, Alados CL, et al. Spatial vegetation patterns and imminent desertification in Mediterranean arid ecosystems. Nature, 2007, 449: 213-217
[25] Moreno-De Las Heras M, Saco PM, Willgoose GR, et al. Assessing landscape structure and pattern fragmentation in semiarid ecosystems using patch-size distributions. Ecological Applications, 2011, 21: 2793-2805
[26] Bruzzone O, Easdale MH. Rhythm of change of trend-cycles of vegetation dynamics as an early warning indicator for land management. Ecological Indicators, 2021, 126: 107663
[27] Siteur K, Siero E, Eppinga MB, et al. Beyond turing: The response of patterned ecosystems to environmental change. Ecological Complexity, 2014, 20: 81-96
[28] Zhu QA, Chen H, Peng CH, et al. An early warning signal for grassland degradation on the Qinghai-Tibetan Plateau. Nature Communications, 2023, 14: 6406
[29] Li CJ, Fu BJ, Wang S, et al. Climate-driven ecological thresholds in China's drylands modulated by grazing. Nature Sustainability, 2023, 6: 1363-1372
[30] Johnston AS, Meade A, Ardö J, et al. Temperature thresholds of ecosystem respiration at a global scale. Nature Ecology & Evolution, 2021, 5: 487-494
[31] Fu Z, Ciais P, Makowski D, et al. Uncovering the critical soil moisture thresholds of plant water stress for European ecosystems. Global Change Biology, 2022, 28: 2111-2123
[32] Sun MZ, Li XY, Xu H, et al. Drought thresholds that impact vegetation reveal the divergent responses of vegetation growth to drought across China. Global Change Bio-logy, 2024, 30: e16998
[33] Maestre FT, Eldridge DJ, Soliveres S, et al. Structure and functioning of dryland ecosystems in a changing world. Annual Review of Ecology, Evolution, and Systematics, 2016, 47: 215-237
[34] Pi K, Bieroza M, Brouchkov A, et al. The cold region critical zone in transition: Responses to climate warming and land use change. Annual Review of Environment and Resources, 2021, 46: 111-134
[35] Berdugo M, Vidiella B, Solé RV, et al. Ecological mechanisms underlying aridity thresholds in global drylands. Functional Ecology, 2022, 36: 4-23
[36] Groffman PM, Baron JS, Blett T, et al. Ecological thresholds: The key to successful environmental management or an important concept with no practical application? Ecosystems, 2006, 9: 1-13
[37] Adeel Z, Safriel U, Niemeijer D, et al. Ecosystems and Human Well-being: Desertification Synthesis. Washington DC, USA: World Resources Institute, 2005
[38] Li XY, Piao SL, Huntingford C, et al. Global variations in critical drought thresholds that impact vegetation. National Science Review, 2023, 10: nwad049
[39] Zhang FY, Quan Q, Ma FF, et al. When does extreme drought elicit extreme ecological responses? Journal of Ecology, 2019, 107: 2553-2563
[40] Reynolds JF, Stafford Smith DM, Lambin EF, et al. Global desertification: Building a science for dryland development. Science, 2007, 316: 847-851
[41] Sterk G, Boardman J, Verdoodt A. Desertification: History, causes and options for its control. Land Degradation & Development, 2016, 27: 1783-1787
[42] Reynolds JF, Grainger A, Stafford Smith DM, et al. Scientific concepts for an integrated analysis of desertification. Land Degradation & Development, 2011, 22: 166-183
[43] Yin XW, Feng Q, Li Y, et al. An interplay of soil sali-nization and groundwater degradation threatening coexistence of oasis-desert ecosystems. Science of the Total Environment, 2022, 806: 150599
[44] Kinzig AP, Ryan P, Etienne M, et al. Resilience and regime shifts assessing cascading effects. Ecology and Society, 2006, 11: 20
[45] Bardgett RD, Bullock JM, Lavorel S, et al. Combatting global grassland degradation. Nature Reviews Earth & Environment, 2021, 2: 720-735
[46] Schuster MZ, Pelissari A, de Vioraes A, et al. Grazing intensities affect weed seedling emergence and the seed bank in an integrated crop-livestock system. Agriculture, Ecosystems & Environment, 2016, 232: 232-239
[47] 侯扶江, 南志标, 肖金玉, 等. 重牧退化草地的植被、土壤及其耦合特征. 应用生态学报, 2002, 13(8): 915-922
[48] Isbell F, Reich PB, Tilman D, et al. Nutrient enrichment, biodiversity loss, and consequent declines in ecosystem productivity. Proceedings of the National Academy of Sciences of the United States of America, 2013, 110: 11911-11916
[49] Rietkerk M, Dekker SC, De Ruiter PC, et al. Self-organized patchiness and catastrophic shifts in ecosystems. Science, 2004, 305: 1926-1929
[50] Berdugo M, Kéfi S, Soliveres S, et al. Plant spatial patterns identify alternative ecosystem multifunctionality states in global drylands. Nature Ecology & Evolution, 2017, 1: 0003
[51] Gillson L, Hoffman MT. Rangeland ecology in a changing world. Science, 2007, 315: 53-54
[52] Eldridge DJ, Soliveres S, Bowker MA, et al. Grazing dampens the positive effects of shrub encroachment on ecosystem functions in a semi-arid woodland. Journal of Applied Ecology, 2013, 50: 1028-1038
[53] Zhang M, Delgado-Baquerizo M, Li G, et al. Experimental impacts of grazing on grassland biodiversity and function are explained by aridity. Nature Communications, 2023, 14: 5040
[54] Cingolani AM, Noy-Meir I, Díaz S. Grazing effects on rangeland diversity: A synthesis of contemporary models. Ecological Applications, 2005, 15: 757-773
[55] Huang M, Sang C, Zhao JX, et al. Grazing exclusion altered the pattern of the soil seed bank but not the aboveground vegetation along an altitudinal gradient in alpine grassland. Land Degradation & Development, 2022, 33: 3901-3913
[56] 汪鹏斌, 宋美娟, 童永尚, 等. 保护播种对高寒区刈割型混播草地产草量及品质的影响. 草地学报, 2021, 29(8): 1818-1827
[57] Zhang W, Zhang JL. Scaling effects on landscape metrics in alpine meadow on the central Qinghai-Tibetan Pla-teau. Global Ecology and Conservation, 2021, 29: e01742
[58] Zelnik YR, Kinast S, Yizhaq H, et al. Regime shifts in models of dryland vegetation. Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences, 2013, 371: 20120358
[59] Kéfi S, Eppinga MB, De Ruiter PC, et al. Bistability and regular spatial patterns in arid ecosystems. Theoretical Ecology, 2010, 3: 257-269
[60] 赵哈林, 郭轶瑞, 周瑞莲, 等. 植被覆盖对科尔沁沙地土壤生物结皮及其下层土壤理化特性的影响. 应用生态学报, 2009, 20(7): 1657-1663
[61] 李新荣, 张志山, 黄磊, 等. 我国沙区人工植被系统生态-水文过程和互馈机理研究评述. 科学通报, 2013, 58(增刊1): 397-410
[62] Wang GH, Zhao WZ, Liu H, et al. Changes in soil and vegetation with stabilization of dunes in a desert-oasis ecotone. Ecological Research, 2015, 30: 639-650
[63] Wang S, Cheng WL, Tan HY, et al. Study on diversity of poisonous weeds in grassland of the Ili Region in Xinjiang. Agronomy, 2024, 14: 330
[64] Lin L, Cao GM, Xu XL, et al. Kobresia pygmaea mea-dows as disclimax communities in the same geographic and climatic environments in Qinghai-Tibet Plateau, China. Journal of Plant Ecology, 2023, 16: rtad010
[65] 马凯凯, 徐长林, 李颖, 等. 高寒草甸冷季牧场不同休牧期对土壤种子库的影响. 草地学报, 2022, 30(8): 2100-2107
[66] Zhang ZC, Liu Y, Sun J, et al. Suitable duration of gra-zing exclusion for restoration of a degraded alpine mea-dow on the eastern Qinghai-Tibetan Plateau. Catena, 2021, 207: 105582