Holocene environmental change in Rotsee and its impact on sedimentary carbon storage.

IF 1.7 3区地球科学 Q4 ENVIRONMENTAL SCIENCES

Journal of Paleolimnology Pub Date : 2025-01-01 Epub Date: 2025-06-11 DOI:10.1007/s10933-025-00361-3

Cindy De Jonge, Nathalie Dubois, S Nemiah Ladd, Longhui Deng, Niroshan Gajendra, Negar Haghipour, Carsten J Schubert, Mark Lever

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Abstract

To assess the long-term impact of climate change and human influence on lakes and their sedimentary carbon storage, paleo-environmental approaches using well-dated lake sediment cores can be employed. Here, we reconstruct carbon mass accumulation rates for organic and inorganic carbon since 13 ka BP in Rotsee, a perialpine lake near the Swiss Alps, using a 12-m sediment core. A multiproxy approach (XRF, carbon and nitrogen isotopes, organic macromolecule chemical compositions, aDNA) was used to explore changes in the lake system that affect sedimentary carbon storage. The Early Holocene (11.8-7 cal ka BP) was characterized by a mixed phytoplankton and watershed-derived provenance of organic matter, and the deposition of inorganic and organic sedimentary carbon. Warming during the Holocene Thermal Maximum (9.8-8.8 cal ka BP) increased sedimentary carbon storage. In the Mid- to Late Holocene (7-1 cal ka BP), the sedimentary record indicates an increased influx of allochthonous, vascular plant-derived organic matter, and low production or conservation of phytoplankton-derived carbon. Organic carbon storage increased, while inorganic carbon became negligible. Larger deforestation events, potentially during Neolithic times (around 4 ka BP), but especially during Roman times (2 ka BP), coincided with further increased organic carbon MARs. Recent sediments, influenced by eutrophication in the last century, show higher carbon accumulation rates compared to earlier Holocene periods. Rotsee serves as a case study of how climate warming and human land use changes have influenced lake development and sedimentary carbon6 storage, with broader implications for understanding carbon dynamics in high altitude lakes and their future carbon balance.

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罗舍全新世环境变化及其对沉积碳储量的影响

为了评估气候变化和人类活动对湖泊及其沉积碳储量的长期影响，可以采用使用年代确定的湖泊沉积物岩心的古环境方法。本文利用12 m沉积物岩心，重建了瑞士阿尔卑斯山脉附近的Rotsee湖13ka BP以来有机碳和无机碳的质量积累速率。采用多代理方法（XRF、碳氮同位素、有机大分子化学组成、aDNA）探讨湖泊系统变化对沉积碳储量的影响。早全新世（11.8-7 cal ka BP）以浮游植物与流域混合的有机质来源为主要特征，沉积碳以无机碳和有机碳为主。全新世热极大期（9.8 ~ 8.8 cal ka BP）的升温增加了沉积碳储量。在全新世中晚期（7-1 cal ka BP），沉积记录表明外来维管植物来源的有机质流入增加，浮游植物来源的碳产生或保存较低。有机碳储量增加，而无机碳储量变得微不足道。更大规模的森林砍伐事件可能发生在新石器时代（大约距今4 ka BP），但尤其是在罗马时代（距今2 ka BP），与有机碳含量进一步增加相吻合。最近的沉积物受上世纪富营养化的影响，显示出比全新世早期更高的碳积累速率。Rotsee作为气候变暖和人类土地利用变化如何影响湖泊发展和沉积碳6储存的案例研究，对了解高海拔湖泊的碳动态及其未来的碳平衡具有更广泛的意义。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Journal of Paleolimnology 地学-地球科学综合

CiteScore

3.70

自引率

9.50%

发文量

审稿时长

3 months

期刊介绍： The realization that a historical perspective is often useful, if not essential, to the understanding of most limnological processes has resulted in the recent surge of interest in paleolimnology. The main aim of the Journal of Paleolimnology is the provision of a vehicle for the rapid dissemination of original scientific work dealing with the reconstruction of lake histories. Although the majority of papers deal with lakes, paleoenvironmental studies of river, wetland, peatland and estuary systems are also eligible for publication. The Journal of Paleolimnology, like the subject itself, is multidisciplinary in nature, and papers are published that are concerned with all aspects (e.g. biological, chemical, physical, geological, etc.) of the reconstruction and interpretation of lake histories. Both applied and more theoretical papers are equally encouraged. The Journal of Paleolimnology will continue to be a major repository for papers dealing with climatic change, as well as other pressing topics, such as global environmental change, lake acidification, eutrophication, long-term monitoring, and other aspects of lake ontogeny. Taxonomic and methodological papers are also acceptable provided they are of relatively broad interest. New equipment designs are frequently featured. In addition to original data and ideas, the Journal of Paleolimnology also publishes review articles, commentaries and program announcements. A relevant Book Review Section is also featured.