Long-term patterns and drivers of carbon burial variations in alpine lakes of Northwest Yunnan, China under regional warming

doi:10.13287/j.1001-9332.202508.033

Abstract

Abstract: Lakes are crucial terrestrial carbon sinks for the Earth’s surface systems, where the burial and transformation of total organic carbon (OC) and inorganic carbon (IC) are strongly influenced by watershed surface processes. In alpine regions with limited direct human impact, long-term warming trends can enhance key proce-sses, such as algal growth and the mineralization of organic matter, thereby altering OC and IC accumulation and burial dynamics. We examined spatial patterns, synergistic relationships and controlling factors of carbon burial under regional warming across six alpine lakes in northwestern Yunnan (deep lakes: Dinggongniang Co, Gaigong Co Na, Wodi Co; shallow lakes: Dinggong Co, Bigu Tianchi, Shudu Lake), by employing multiple proxies including total nitrogen, chlorophyll, OC and IC contents, combined with climate reconstruction data. Results showed that 1.14 ℃ increase in temperature over the past 150 years had significantly reshaped carbon sequestration across lakes. The response magnitude of primary productivity to temperature increases in shallow lakes (Bigu Tianchi: 39%; Shudu Lake: 58%; Dinggong Co: 30%) was significantly greater than in deep lakes (Dinggongniang Co: 14%; Gaigong Co Na: 7%; Wodi Co: 20%). Distinct carbon cycling processes were observed between lake types. In deep lakes, algal contributions to OC were negligible while enhancing synchronous OC-IC deposition, indicating stratification simultaneously inhibited autochthonous carbon burial while promoting organic matter preservation. Conversely, there were strong chlorophyll-OC correlations with weakened OC-IC coupling in shallow lakes, revealing algal-dominated organic carbon production coupled with enhanced mineralization processes. Furthermore, atmospheric deposition altered inorganic carbon burial regimes through nitrogen enrichment in alkaline waters (Dinggongniang Co, Gaigong Co Na, Wodi Co, Shudu Lake, Bigu Tianchi). Elevated pH promoted carbonate precipitation and IC accumulation, while acidic inputs suppressed IC burial in acidic lake (Dinggong Co) and modified OC-IC burial relationship. Overall, the carbon burial processes in alpine lakes exhibited different responses to regional environmental changes, which were strongly related to lake depth, pH, and other limnological characteristics.

Key words: alpine lake, climate change, carbon burial, synergistic interaction, influencing factor

LIU Zhi, WANG Lu, CHEN Guangjie, DAI Pinghui, CHEN Junyuan, MA Qian, KONG Lingyang, HUANG Linpei, ZHU Yun, LI Jing. Long-term patterns and drivers of carbon burial variations in alpine lakes of Northwest Yunnan, China under regional warming[J]. Chinese Journal of Applied Ecology, 2025, 36(8): 2475-2486.

References

[1] Sobek S, Tranvik LJ, Prairie YT, et al. Patterns and regulation of dissolved organic carbon: An analysis of 7500 widely distributed lakes. Limnology and Oceanography, 2007, 52: 1208-1219
[2] Verpoorter C, Kutser T, Seekell DA, et al. A global inventory of lakes based on high-resolution satellite imagery. Geophysical Research Letters, 2014, 41: 6396-6402
[3] Zhou SF, Long H, Chen WZ, et al. Temperature seasonality regulates organic carbon burial in lake. Nature Communications, 2025, 16: 1049
[4] Pilla RM, Griffiths NA, Gu L, et al. Anthropogenically driven climate and landscape change effects on inland water carbon dynamics: What have we learned and where are we going? Global Change Biology, 2022, 28: 5601-5629
[5] Battin TJ, Lauerwald R, Bernhardt ES, et al. River ecosystem metabolism and carbon biogeochemistry in a changing world. Nature, 2023, 613: 449-459
[6] Regnier P, Resplandy L, Najjar RG, et al. The land-to-ocean loops of the global carbon cycle. Nature, 2022, 603: 401-410
[7] Brunet F, Gaiero D, Probst JL, et al. δ¹³C tracing of dissolved inorganic carbon sources in Patagonian rivers (Argentina). Hydrological Processes, 2005, 19: 3321-3344
[8] Liu M, Zhang YL, Shi K, et al. Thermal stratification dynamics in a large and deep subtropical reservoir revealed by high-frequency buoy data. Science of the Total Environment, 2019, 651: 614-624
[9] Adrian R, O’Reilly CM, Zagarese H, et al. Lakes as sentinels of climate change. Limnology and Oceanography, 2009, 54: 2283-2297
[10] Sobek S, Anderson NJ, Bernasconi SM, et al. Low organic carbon burial efficiency in arctic lake sediments. Journal of Geophysical Research: Biogeosciences, 2014, 119, DOI: 10.1002/2014JG002612
[11] 肖启涛, 段洪涛, 张弥, 等. 大型浅水湖泊水体对流混合速率分析. 湖泊科学, 2020, 32(4): 1189-1198
[12] Anderson NJ, Bennion H, Lotter AF. Lake eutrophication and its implications for organic carbon sequestration in Europe. Global Change Biology, 2014, 20: 2741-2751
[13] Ma J, Lai QY, He F, et al. Warming enhances the co-metabolism effect during the decomposition of sediment organic carbon in eutrophic lakes. Bulletin of Environmental Contamination and Toxicology, 2022, 109: 984-989
[14] Hood EW, Williams MW, Caine N. Landscape controls on organic and inorganic nitrogen leaching across an alpine/subalpine ecotone, Green Lakes Valley, Colorado Front Range. Ecosystems, 2003, 6: 31-45
[15] Dong XH, Anderson NJ, Yang XD, et al. Carbon burial by shallow lakes on the Yangtze floodplain and its relevance to regional carbon sequestration. Global Change Biology, 2012, 18: 2205-2217
[16] Martin JB. Carbonate minerals in the global carbon cycle. Chemical Geology, 2017, 449: 58-72
[17] Raza S, Zamanian K, Ullah S, et al. Inorganic carbon losses by soil acidification jeopardize global efforts on carbon sequestration and climate change mitigation. Journal of Cleaner Production, 2021, 315: 128036
[18] 何军, 彭佳, 黄咸雨, 等. 沉积硅藻记录的近40年来神农架大九湖湿地生态水文变化. 应用生态学报, 2024, 35(8): 2247-225
[19] 王燚, 李文珊, 展鹏飞, 等. 若尔盖高原泥炭沼泽土壤微生物空间分布. 应用生态学报, 2024, 35(6): 1705-1715
[20] 李平, 陈光杰, 孔令阳, 等. 近百年来异龙湖有机碳和无机碳埋藏响应水体富营养化的协同变化特征. 中国环境科学, 2023, 43(10): 5389-5402
[21] Huo H, Sun CP. Land surface temperature variations in the Yunnan Province of Southwest China. Environmental Monitoring and Assessment, 2024, 197: 65
[22] Hu ZJ, Yang XD, Anderson NJ, et al. The landscape-atmosphere continuum determines ecological change in alpine lakes of SE Tibet. Ecosystems, 2018, 21: 839-851
[23] 段志诚. 中甸县志. 昆明: 云南民族出版社, 1997: 80-85
[24] 胡竹君. 青藏高原东南缘高山湖泊生态变化与驱动机制. 博士论文. 南京: 中国科学院南京地理与湖泊研究所, 2013
[25] 李静. 滇西北两个高山湖泊近两百年来环境变化及枝角类群落响应特征对比研究. 硕士论文. 昆明: 云南师范大学, 2024
[26] 朱云, 陈光杰, 孔令阳, 等. 青藏高原东南缘高山湖泊藻类响应气候变化和大气沉降的长期特征. 湖泊科学, 2023, 35(6): 2155-2169
[27] Swain EB. Measurement and interpretation of sedimen-tary pigments. Freshwater Biology, 1985, 15: 53-75
[28] Pauli H, Gottfried M, Dullinger S, et al. Recent plant diversity changes on Europe’s mountain summits. Science, 2012, 336: 353-355
[29] Yue WP, Chen F, Davi NK, et al. Little Ice Age coo-ling in the Western Hengduan Mountains, China: A 600-year warm-season temperature reconstruction from tree rings. Climate Dynamics, 2024, 62: 773-790
[30] Li JB, Shi JF, Zhang DD, et al. Moisture increase in response to high-altitude warming evidenced by tree-rings on the southeastern Tibetan Plateau. Climate Dynamics, 2017, 48: 649-660
[31] 曾理, 吴丰昌, 万国江, 等. 中国地区湖泊沉积物中¹³⁷Cs分布特征和环境意义. 湖泊科学, 2009, 21(1): 1-9
[32] 张信宝, 龙翼, 文安邦, 等. 中国湖泊沉积物¹³⁷Cs和²¹⁰Pbex断代的一些问题. 第四纪研究, 2012, 32(3): 430-440
[33] 赵巧华, 徐嘉, 刘玲, 等. 垂向湍流、温、光对浅水湖泊下沉藻类垂向分布的影响. 生态学报, 2021, 41(13): 5465-5475
[34] Kámpf J. Wind-driven overturning, mixing and upwelling in shallow water: A nonhydrostatic modeling study. Journal of Marine Science and Engineering, 2017, 5: 47
[35] 罗东, 李赠, 赵苗苗, 等. 光照和营养对亚热带浅水湖泊初级生产者的复合影响: 基于微宇宙实验研究. 生态学报, 2024, 44(23): 10639-10649
[36] Li JY, Li YR, Liu M, et al. Patterns of thermocline structure and the deep chlorophyll maximum feature in multiple stratified lakes related to environmental drivers. Science of the Total Environment, 2022, 851: 158431
[37] Liu M, Zhang YL, Shi K, et al. Spatial variations of subsurface chlorophyll maxima during thermal stratification in a large, deep subtropical reservoir. Journal of Geophysical Research: Biogeosciences, 2020, 125, DOI: 10.1029/2019JG005480
[38] Galloway JN, Cowling EB. Reactive nitrogen and the world: 200 years of change. Ambio, 2002, 31: 64-71
[39] Galloway JN, Townsend AR, Erisman JW, et al. Transformation of the nitrogen cycle: Recent trends, questions, and potential solutions. Science, 2008, 320: 889-892
[40] Kong H, Lin JT, Zhang YH, et al. High natural nitric oxide emissions from lakes on Tibetan Plateau under rapid warming. Nature Geoscience, 2023, 16: 474-477
[41] Chen JG, Yang HQ, Zeng Y,et al. Combined use of radiocarbon and stable carbon isotope to constrain the sources and cycling of particulate organic carbon in a large freshwater lake, China. Science of the Total Environment, 2018, 625: 27-38
[42] Zhang C, Kong XZ, Xue B, et al. Synergistic effects of climate warming and atmospheric nutrient deposition on the alpine lake ecosystem in the south-eastern Tibetan Plateau during the Anthropocene. Frontiers in Ecology and Evolution, 2023, 11, DOI: 10.3389/fevo.2023.1119840
[43] Venkiteswaran JJ, Schiff SL, Paterson MJ, et al. Changing nitrogen deposition with low δ¹⁵N-NH₄⁺ and δ¹⁵N-NO₃^- values at the experimental lakes area, northwes-tern Ontario, Canada. Facets, 2017, 2: 249-266
[44] Li WK, Wang X, Song W, et al. On the contribution of atmospheric reactive nitrogen deposition to nitrogen burden in a eutrophic Lake in eastern China. Water Research, 2025, 268: 122597
[45] Kang WG, Chen GJ, Wang JY, et al. Assessing the impact of long-term changes in climate and atmospheric deposition on a shallow alpine lake from southeast Tibet. Science of the Total Environment, 2019, 650: 713-724
[46] Woolway RI, Kraemer BM, Lenters JD, et al. Global lake responses to climate change. Nature Reviews Earth & Environment, 2020, 1: 388-403
[47] Hecky RE, Kilham P. Nutrient limitation of phytoplankton in freshwater and marine environments: A review of recent evidence on the effects of enrichment. Limnology and Oceanography, 1988, 33: 796-822
[48] Williamson CE, Morris DP, Pace ML, et al. Dissolved organic carbon and nutrients as regulators of lake ecosystems: Resurrection of a more integrated paradigm. Limnology and Oceanography, 1999, 44: 795-803
[49] Qin BQ, Zhou J, Elser JJ, et al. Water depth underpins the relative roles and fates of nitrogen and phosphorus in lakes. Environmental Science & Technology, 2020, 54: 3191-3198
[50] Ding YQ, Qin BQ, Deng JM, et al. Effects of episodic sediment resuspension on phytoplankton in Lake Taihu: Focusing on photosynthesis, biomass and community composition. Aquatic Sciences, 2017, 79: 617-629
[51] Scheffer M, van Nes EH. Shallow lakes theory revisited: Various alternative regimes driven by climate, nutrients, depth and lake size. Hydrobiologia, 2007, 584: 455-466
[52] Gudasz C, Bastviken D, Steger K, et al. Temperature-controlled organic carbon mineralization in lake sediments. Nature, 2010, 466: 478-481
[53] Tkemaladze GS, Makhashvili KA. Climate changes and photosynthesis. Annals of Agrarian Science, 2016, 14: 119-126
[54] Chafetz H, Rush PF, Utech NM. Microenvironmental controls on mineralogy and habit of CaCO₃ precipitates: An example from an active travertine system. Sedimentology, 1991, 38: 107-126
[55] Lojen S, Dolenec T, Vokal B, et al. C and O stable isotope variability in recent freshwater carbonates (River Krka, Croatia). Sedimentology, 2004, 51: 361-375
[56] Zhao YY, Liu J, Uthaipan K, et al. Dynamics of inorganic carbon and pH in a large subtropical continental shelf system: Interaction between eutrophication, hypo-xia, and ocean acidification. Limnology and Oceanography, 2020, 65: 1359-1379
[57] Taranu ZE, Gregory-Eaves I, Leavitt PR, et al. Acce-leration of cyanobacterial dominance in north temperate-subarctic lakes during the Anthropocene. Ecology Letters, 2015, 18: 375-384
[58] Müller B, Meyer JS, Gáchter R. Alkalinity regulation in calcium carbonate-buffered lakes. Limnology and Oceanography, 2016, 61: 341-352
[59] Missaghi S, Hondzo M, Herb W. Prediction of lake water temperature, dissolved oxygen, and fish habitat under changing climate. Climatic Change, 2017, 141: 747-757
[60] Zhou SL, Sun Y, Huang TL, et al. Reservoir water stratification and mixing affects microbial community structure and functional community composition in a stratified drinking reservoir. Journal of Environmental Management, 2020, 267: 110456
[61] White AF, Blum AE. Effects of climate on chemical weathering in watersheds. Geochimica et Cosmochimica Acta, 1995, 59: 1729-1747
[62] Sobek S, Tranvik LJ, Cole JJ. Temperature indepen-dence of carbon dioxide supersaturation in global lakes. Global Biogeochemical Cycles, 2005, 19, DOI: 10.1029/2004GB002264
[63] Paulsson O, Widerlund A. Diel variations in dissolved oxygen concentration and algal growth in the Laver pit lake, northern Sweden. Applied Geochemistry, 2023, 155: 105725
[64] Hulthe G, Hulth S, Hall POJ. Effect of oxygen on degradation rate of refractory and labile organic matter in continental margin sediments. Geochimica et Cosmochimica Acta, 1998, 62: 1319-1328
[65] Drever JI, Stillings LL. The role of organic acids in mine-ral weathering. Colloids and Surfaces A: Physicochemical and Engineering Aspects, 1997, 120: 167-181
[66] Liu YY, Chen GJ, Meyer-Jacob C, et al. Land-use and climate controls on aquatic carbon cycling and phototrophs in karst lakes of southwest China. Science of the Total Environment, 2021, 751: 141738