Translating deposition rates into erosion rates with landscape evolution modelling

IF 2.8 2区 地球科学 Q2 GEOGRAPHY, PHYSICAL Earth Surface Dynamics Pub Date : 2024-04-18 DOI:10.5194/egusphere-2024-1036
W. Marijn van der Meij
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Abstract

Abstract. Soil erosion is one of the main threats to agricultural food production due to the loss of fertile soil. Determination of erosion rates is essential to quantify the degree of land degradation, but it is inherently challenging to determine temporally dynamic erosion rates over agricultural time scales. Optically Stimulated Luminescence (OSL) dating can provide temporally-resolved deposition rates by determining the last moment of daylight exposure of buried colluvial deposits. However, these deposition rates may differ substantially from the actual hillslope erosion rates. In this study, OSL-based deposition rates were converted to hillslope erosion rates through inverse modelling with soil-landscape evolution model ChronoLorica. This model integrates geochronological tracers into the simulations of soil mixing and redistribution. The model was applied to a kettle hole catchment in north-eastern Germany, which has been affected by tillage erosion over the last 5000 years. The initial shape of the landscape and the land use history are well-constrained, enabling accurate simulations of the landscape evolution that incorporate uncertainties in the model inputs. The calibrated model reveals an increase in erosion rates of almost to orders of magnitude from pre-historic ard ploughing up to recent intensive land management. The simulated rates match well with independent age controls from the same catchment. Uncertainty in the reconstructed initial landscape and land use histories had a minor influence of 12–16 % on the simulated rates. The simulations showed that the deposition rates were on average 1.5 higher than the erosion rates due to the ratio of erosional and depositional area. Recent artificial drainage and land reclamation have increased deposition rates up to five times the erosion rates, emphasizing the need of cautious interpretation of deposition rates as erosion proxies. This study demonstrates the suitability of ChronoLorica for upscaling experimental geochronological data to better understand landscape evolution in agricultural settings.
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利用地貌演变模型将沉积率转化为侵蚀率
摘要由于肥沃土壤的流失,水土流失是农业粮食生产的主要威胁之一。水土流失率的测定对于量化土地退化程度至关重要,但要测定农业时间尺度上的时间动态水土流失率本身就具有挑战性。光致发光(OSL)测年法可以通过确定被掩埋的冲积层在日光下的最后暴露时间,提供时间分辨的沉积速率。然而,这些沉积速率可能与实际的山坡侵蚀速率有很大差异。在这项研究中,通过使用土壤-景观演变模型 ChronoLorica 进行反模拟,将基于 OSL 的沉积速率转换为山坡侵蚀速率。该模型将地质年代示踪剂融入土壤混合和再分布的模拟中。该模型被应用于德国东北部的一个水壶洞集水区,该集水区在过去的 5000 年中一直受到耕作侵蚀的影响。地貌的初始形状和土地使用历史受到了很好的约束,因此能够准确模拟地貌的演变,并将模型输入的不确定性考虑在内。校准后的模型显示,从史前的犁耕到最近的集约化土地管理,侵蚀率几乎呈数量级增长。模拟的侵蚀率与同一集水区的独立年龄对照非常吻合。重建的初始地貌和土地利用历史的不确定性对模拟速率的影响较小,仅为 12-16%。模拟结果表明,由于侵蚀面积和沉积面积之比,沉积速率平均比侵蚀速率高 1.5。最近的人工排水和土地开垦使沉积率增加到侵蚀率的五倍,这强调了谨慎解释沉积率作为侵蚀代用指标的必要性。这项研究表明,ChronoLorica 适用于放大实验性地质年代数据,以更好地了解农业环境中的地貌演变。
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来源期刊
Earth Surface Dynamics
Earth Surface Dynamics GEOGRAPHY, PHYSICALGEOSCIENCES, MULTIDISCI-GEOSCIENCES, MULTIDISCIPLINARY
CiteScore
5.40
自引率
5.90%
发文量
56
审稿时长
20 weeks
期刊介绍: Earth Surface Dynamics (ESurf) is an international scientific journal dedicated to the publication and discussion of high-quality research on the physical, chemical, and biological processes shaping Earth''s surface and their interactions on all scales.
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