区域增温下滇西北高山湖泊碳埋藏变化的长期模式及其驱动因子

doi:10.13287/j.1001-9332.202508.033

摘要/Abstract

摘要： 湖泊是地表系统重要的陆地碳汇之一,其有机碳(OC)与无机碳(IC)的埋藏量及其迁移转化特征受流域地表过程影响明显。在人类活动直接影响较弱的高山地区,长期增温会促进藻类生长,并加速有机质的矿化作用,改变OC和IC的累积及其埋藏特征。本文选取滇西北地区6个高山湖泊(深水湖泊:丁公娘错、盖公错纳、沃迪错;浅水湖泊:丁公错、碧沽天池、属都湖)开展沉积物调查,基于总氮、叶绿素、OC和IC含量等指标,结合气候重建等资料,甄别区域增温下高山湖泊OC和IC埋藏变化的空间模式、协同特征及其影响因子。结果表明: 近150年来区域升温幅度达1.14 ℃,高山湖泊的碳埋藏格局出现了明显变化。浅水湖泊的初级生产力对气温上升的响应强度(碧沽天池,39%;属都湖,58%;丁公错,30%)显著高于深水湖泊(丁公娘错,14%;盖公错纳,7%;沃迪错,20%)。不同水深的高山湖泊在碳循环过程中表现出明显差异:深水湖泊中藻类对OC的贡献较小,但显著促进了OC和IC的同步增加,表明热力分层抑制藻源碳埋藏而促进OC保存;浅水湖泊叶绿素与OC呈显著正相关,而OC和IC协同减弱,体现了在浅水环境中藻类对OC库的重要贡献和更显著的有机质矿化过程。此外,大气沉降过程通过氮素富集改变了湖泊IC埋藏模式,在碱性水体(丁公娘错、盖公错纳、沃迪错、属都湖、碧沽天池)中藻类生长提高了水体pH值并显著促进了碳酸盐沉淀和IC累积;而酸性物质的直接输入则抑制了酸性湖泊(丁公错)的IC埋藏,并改变了OC和IC埋藏变化的协同特征。高山湖泊碳埋藏过程对区域增温的响应模式主要与湖泊水深、酸碱度等有关。

关键词: 高山湖泊, 气候变化, 碳埋藏, 协同特征, 影响因子

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

刘智, 王露, 陈光杰, 代平慧, 陈俊沅, 马欠, 孔令阳, 黄林培, 朱云, 李静. 区域增温下滇西北高山湖泊碳埋藏变化的长期模式及其驱动因子[J]. 应用生态学报, 2025, 36(8): 2475-2486.

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.

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