考虑到水文模型和 GCM 的不确定性,BMP 对流域气候适应的有效性和复原力

IF 4.8 2区 环境科学与生态学 Q1 ENVIRONMENTAL SCIENCES
Bowen Zhang , Ying Chen , Xingwei Chen , Lu Gao , Haijun Deng , Meibing Liu
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引用次数: 0

摘要

气候变化会对流域水文和水质过程产生重大影响。最佳管理实践(BMP)可作为适应战略,以消除气候变化对沉积物和总氮(TN)负荷的影响。气候变化适应研究中的一个主要争议问题是这种变化的高度不确定性。以往的研究很少关注气候变化和流域模型参数不确定性的综合影响,而这可能是气候变化适应研究中不确定性的主要来源。本研究探讨了中国东南部山美水库流域(SMW)在未来气候变化条件下,BMP 在减少泥沙和 TN 负荷方面的有效性和恢复力(定义为在气候变化条件下的持续有效性)。在年化农业非点源(AnnAGNPS)模型中应用了 10 个大气环流模型(GCM)提供的 2031 年至 2060 年 SSP1-2.6、SSP2-4.5、SSP3-7.0 和 SSP5-8.5 情景下的气候变化预测,以评估 4 种 BMP(河岸缓冲区(RB)、免耕(NT)、减少施肥(FR)和平行梯田(PT))的有效性和恢复力。采用了 10 个 GCM 和 10 个行为参数组的集合平均值,以减少水文模型参数和 GCM 带来的不确定性。结果表明,未来 SMW 的年平均气温和降水量都将增加。从季节尺度来看,四季平均气温都将升高,降水量将在夏秋两季减少,而在春冬两季增加。年沉积物和 TN 负荷将减少,但春季和冬季的负荷将增加。在未来气候条件下,BMP 可作为减少沉积物和 TN 负荷的有效气候适应战略,其中 PT 是最有效的选择。结构性 BMP 在减少春季和冬季的沉积物和 TN 负荷方面更为有效,而非结构性 BMP 在减少夏季和秋季的负荷方面更为有效。当未来流域径流变化轻微或气候敏感性降低时,BMP 的复原力更强,春季和冬季的 BMP 复原力高于夏季和秋季。本研究旨在通过实施 BMP 为流域提供系统参考,以减轻气候变化的影响,并扩展 AnnAGNPS 模型的应用范围。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Effectiveness and resilience of BMPs to watershed climate adaptation considering the uncertainty of hydrological model and GCMs

Effectiveness and resilience of BMPs to watershed climate adaptation considering the uncertainty of hydrological model and GCMs

Climate change significantly impacts catchment hydrologic and water quality processes. Best management practices (BMPs) can serve as adaptation strategies to negate the impact of climate change on sediment and total nitrogen (TN) loads. One major controversial issue in climate change adaptation studies is the highly uncertain nature of such changes. Previous studies have rarely focused on the combined impact of the uncertainty in climate change and watershed model parameters, which could be the main sources of uncertainty in climate change adaptation research. In this study, the effectiveness and resilience (defined as continued effectiveness under a changing climate) of BMPs in reducing sediment and TN loads were explored under future climate change in the Shanmei Reservoir watershed (SMW) of Southeast China. Climate change projections provided by 10 general circulation models (GCMs) under the SSP1-2.6, SSP2-4.5, SSP3-7.0, and SSP5-8.5 scenarios from 2031 to 2060 were applied in the Annualized Agricultural Nonpoint Source (AnnAGNPS) model to evaluate the effectiveness and resilience of 4 BMPs (riparian buffers (RB), no-tillage (NT), fertilization reduction (FR), and parallel terraces (PT)). The ensemble average of 10 GCMs and 10 behavior parameter groups were adopted to reduce the uncertainty resulting from the hydrological model parameters and GCMs. The results indicated that the average annual temperature and precipitation in the SMW will increase in the future. On a seasonal scale, the average temperature during all seasons will increase, and precipitation will decrease in summer and autumn but increase in spring and winter. The annual sediment and TN loads will decrease, but the loads in spring and winter will increase. BMPs could be effective as climate adaptation strategies for reducing sediment and TN loads under future climate conditions, with PT as the most effective option. Structural BMPs were more effective in reducing sediment and TN loads in spring and winter, whereas nonstructural BMPs were more effective in reducing loads in summer and autumn. BMPs were more resilient when future watershed runoff changes were slight or climate sensitivity was reduced, with higher BMP resilience in spring and winter than in summer and autumn. This study aimed to provide systematic references for watersheds through the implementation of BMPs for mitigating the effects of climate change and extending the boundaries of the AnnAGNPS model application.

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来源期刊
Climate Risk Management
Climate Risk Management Earth and Planetary Sciences-Atmospheric Science
CiteScore
8.20
自引率
4.50%
发文量
76
审稿时长
30 weeks
期刊介绍: Climate Risk Management publishes original scientific contributions, state-of-the-art reviews and reports of practical experience on the use of knowledge and information regarding the consequences of climate variability and climate change in decision and policy making on climate change responses from the near- to long-term. The concept of climate risk management refers to activities and methods that are used by individuals, organizations, and institutions to facilitate climate-resilient decision-making. Its objective is to promote sustainable development by maximizing the beneficial impacts of climate change responses and minimizing negative impacts across the full spectrum of geographies and sectors that are potentially affected by the changing climate.
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