Hydrological response of catchments to declining snow and ice storage

流域对积雪和冰蓄积减少的水文响应

• 批准号: RGPIN-2015-03844
• 负责人: Kinnard, Christophe
• 金额: $ 1.6万
• 依托单位: Université du Québec à Trois-Rivières
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2017
• 资助国家: 加拿大
• 起止时间: 2017-01-01 至 2018-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=634184
• 关键词: Hydrological; response; catchments; declining; snow

The ongoing and projected climate change will progressively reduce the seasonal (snow) and semi-permanent (glaciers, permafrost) storage of frozen water in mountain and other cold climate catchments. These cryospheric changes could drastically modify the nivo-glacial river regime of these catchments, redefining new risk levels (drought, floods) as well as freshwater-derived ecosystems services (e.g. agriculture culture irrigation, hydroelectricity production). This 5-year research program aims to study the impact of climate variability on the cryosphere and related meltwater contribution to catchment hydrology using a combined observational-modelling approach. The program will pursue three objectives: (1) to estimate climate change impacts on meltwater fluxes from glacierized mountain catchments; (2) to test the ability of snow models to simulate spatio-temporal snow dynamic; (3) to assess the ability of simple hydrological models to predict complex hydrological systems in future climates. Two experimental catchments with different topography, climate and cryospheric storage will be studied for this purpose: the Rapel River in Chile (Mediterranean climate, partly glacierized) and the Matawin River in Canada (snow dominated, continental-humid climate). Our proposed methodological approach will (1) use glacio-hydrological models as a learning tool to better constrain the dominant processes in the catchment, and (2) quantify the climate sensitivity of these processes in order to provide a physical understanding of potential future changes. Results from sensitivity analyses can be easily communicated to water managers and applied to the continuously refining climate projections. A distributed SNow Observing System (SNOS) will be deployed in one catchment (Matawin) to study the spatio-temporal variability of snow accumulation and meltwater runoff generation, and to provide an observational basis for model testing. Are simple hydrological models able to extrapolate beyond the present climate conditions? This ongoing problem in hydrology will be addressed by challenging common conceptual hydrological models to reproduce synthetic river discharge data generated by a 'virtual catchment' with different boundary conditions (climate, topography). A spatially-distributed, physically-based hydrological model will be used as a virtual catchment platform. We expect the results generated by this research program to bring both practical valuable information for water managers seeking adaptive strategies as well as theoretical advances in the field of snow and ice hydrology (ability of models to simulate present and future snow and ice hydrology).

正在进行和预计的气候变化将逐步减少山区和其他寒冷气候集水区的季节性（雪）和半永久性（冰川、永久冻土）冰冻水储存。这些冰冻圈的变化可能会极大地改变这些流域的尼沃冰川河流状况，重新定义新的风险水平（干旱、洪水）以及淡水衍生的生态系统服务（例如农业灌溉、水力发电）。这项为期五年的研究计划旨在利用观测-建模相结合的方法，研究气候变化对冰冻圈的影响以及相关融水对流域水文的贡献。该计划将追求三个目标：（1）估计气候变化对冰川山区流域融水通量的影响； （2）测试雪模型模拟时空雪动态的能力； （3）评估简单水文模型预测未来气候复杂水文系统的能力。为此目的，将研究两个具有不同地形、气候和冰冻圈储存的实验流域：智利的拉佩尔河（地中海气候，部分冰川）和加拿大的马塔温河（以雪为主的大陆性湿润气候）。我们提出的方法将（1）使用冰川水文模型作为学习工具，以更好地限制流域内的主导过程，（2）量化这些过程的气候敏感性，以便提供对未来潜在变化的物理理解。敏感性分析的结果可以轻松传达给水资源管理者，并应用于不断完善的气候预测。将在一个流域（Matawin）部署分布式积雪观测系统（SNOS），研究积雪和融水径流产生的时空变化，并为模型测试提供观测基础。简单的水文模型是否能够推断出当前气候条件之外的情况？这一持续存在的水文学问题将通过挑战常见的概念水文模型来解决，以重现由具有不同边界条件（气候、地形）的“虚拟流域”生成的合成河流流量数据。空间分布的、基于物理的水文模型将被用作虚拟流域平台。我们期望该研究项目产生的结果既能为寻求适应性策略的水资源管理者带来实用的有价值的信息，又能为冰雪水文学领域的理论进步（模型模拟当前和未来的冰雪水文学的能力）带来实用价值。