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水文学シミュレーションにおける側方流の役割を理解するための水トレーサーツール(A Water Tracer Tool to Understand the Role of Lateral Flow in Hydrologic Simulations)

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2024-07-31 パシフィック・ノースウェスト国立研究所(PNNL)

科学者たちは、流域スケールでの水とエネルギーの組織化に重要な役割を果たす側方流のモデリングの重要性を理解するために、先進的な水文学モデルWRF-Hydroに水トレーサーツールを開発しました。このツールを使用して、降水イベントが流域内をどのように移動し、最終的に流出するかを追跡しました。シミュレーションを側方流ありとなしで実行した結果、異なる水の経路と時間スケールが明らかになり、乾燥した流域では水の滞在時間が長くなり、湿った流域では短くなることが分かりました。この新しいツールは、広範な科学コミュニティに水の動きを理解するための強力な手段を提供し、モデルの改善点を特定するのにも役立ちます。

<関連情報>

WRF-Hydroに水トレーサーモデルを統合し、水文シミュレーションにおける側方流動の影響を評価する Integrating a Water Tracer Model Into WRF-Hydro for Characterizing the Effect of Lateral Flow in Hydrologic Simulations

Huancui Hu, L. Ruby Leung, Francina Dominguez, David Gochis, Xingyuan Chen, Stephen Good, Aubrey Dugger, Laurel Larsen, Michael Barlage
Water Resources Research  Published: 08 July 2024
DOI:https://doi.org/10.1029/2023WR034938

水文学シミュレーションにおける側方流の役割を理解するための水トレーサーツール(A Water Tracer Tool to Understand the Role of Lateral Flow in Hydrologic Simulations)

Abstract

Most current land models approximate terrestrial hydrological processes as one-dimensional vertical flow, neglecting lateral water movement from ridges to valleys. Such lateral flow is fundamental at catchment scales and becomes crucial for finer-scale land models. To test the effect of incorporating lateral flow toward three-dimensional representations of hydrological processes in the next generation land models, we integrate a water tracer model into the WRF-Hydro framework to track water movement from precipitation to discharge and evapotranspiration. This hydrologic-tracer integrated system allows us to identify the key mechanisms by which lateral flow affects the flow paths and transit times in WRF-Hydro. By comparing modeling experiments with and without lateral routing in two contrasting catchments, we determine the impacts of lateral flow on the transit times of precipitation event-water. Results show that with limited hydrologic connectivity, lateral flow extends the transit times by reducing (increasing) event-water drainage loss (accumulation) in ridges (valleys) and allowing reinfiltration of infiltration-excess flow, which is missing in most land models. On the contrary with high hydrologic connectivity, lateral flow can effectively accelerate the water release to streams and reduce the transit time. However, the transit times are substantially underestimated by the model compared with isotope-derived estimates, indicating model limitations in representing flow paths and transit times. This study provides some insights on the fundamental differences in terrestrial hydrology simulated by land models with and without lateral flow representation.

Key Points

  • A water tracer model has been integrated with WRF-Hydro to examine the role of lateral flow in terrestrial hydrological processes
  • Accounting for lateral flow lengthens the transit times of precipitation in conditions with limited hydrology connectivity and vice versa
  • Modeled results underestimate transit times compared to isotope-derived estimates in the H.J. Andrews Experimental Forest
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