Evaluating the Atibaia River hydrology using JULES6.1

Chou, Hsi-Kai; Ávila, Ana Maria Heuminski de; Bray, Michaela

doi:10.5194/gmd-15-5233-2022

Cited by 3 publications

(2 citation statements)

References 32 publications

(30 reference statements)

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“…Despite increased complexities, their hydrological modeling components are still based on conventional hydrological models. For example, the latest JULES model from the UK is a cutting‐edge land surface model, and its hydrological model component is based on two well‐known hydrological models (Chou et al., 2022), namely, PDM and TOPMODEL. The Noah‐MP land surface model has been coupled into the WRF‐Hydro model in modeling subsurface flow routing, overland flow routing and channel flow routing.…”

Section: Resultsmentioning

confidence: 99%

Hydrological Model Adaptability to Rainfall Inputs of Varied Quality

Wang

Zhuo

Han

et al. 2023

Water Resources Research

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Hydrological models serve as useful tools for flood forecasting and water resource management (Bárdossy & Singh, 2008). Rainfall data are the primary input for hydrological models. Usually, rain gauge observations are considered the most reliable rainfall source (so-called "ground truth"). However, due to the insufficient rain gauge density, rainfall estimations from weather radars, satellites, reanalysis, and Numerical Weather Prediction (NWP) model products have also been widely applied for hydrological applications.A plethora of studies employed hydrological modeling to evaluate the reliability of various state-of-the-art rainfall data sets in different regions. Many of them suggested that despite the varied accuracy of rainfall data compared with observations, some rainfall data sets could reproduce satisfactory streamflow simulations after model recalibration, and could even perform as well as using the observed rainfall (

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Section: Resultsmentioning

confidence: 99%

Hydrological Model Adaptability to Rainfall Inputs of Varied Quality

Wang

Zhuo

Han

et al. 2023

Water Resources Research

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“…The JULES model was developed by the UK Met Office evolved from the Met Office Surface Exchange Scheme (MOSES, Cox et al, 1999), which was the land surface scheme of UK Met Office Earth System Model, now used as a standalone land surface model to simulate the carbon fluxes (Clark et al, 2011), water, energy, andmomentum (Best et al, 2011) between the land surface and the atmosphere. The model has been increasingly used for hydrological assessment (Zulkafli et al, 2013;Le Vine et al, 2016;Martínezde la Torre et al, 2019;Yang et al, 2019;Chou et al, 2022). However, the JULES model is rarely used in China, especially for hydrological simulation.…”

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confidence: 99%

Evaluating future hydrological changes in China under climate change

Gao,

Chen,

Marthews

et al. 2024

Preprint

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Abstract. Projecting and understanding future hydrological changes in China are critical for effective water resource management and adaptation planning in response to climate variability. However, few studies have investigated runoff variability and flood and drought risks under climate change scenarios for the entire region of China at high resolution. In this study, we use the Joint UK Land Environment Simulator (JULES), specifically tailored for simulating hydrological processes in China at a 0.25-degree resolution. Downscaled and bias-corrected forcing data from Global Climate Models (GCMs), using the bias-correction and spatial disaggregation (BCSD) method, were used to drive the JULES model to project future hydrological processes under medium (SSP245) and high (SSP585) emission scenarios. The results indicate that annual runoff in China is projected to increase significantly under the high emission scenario, notably in the eastern and southern basins. Wetter summers and drier winters are expected in the south, while the opposite trend is expected in the north. Wetter conditions in the near future and drier summers in the far future are expected in northern China. Shifts from drier to wetter conditions are projected in the southeast and southwest areas, while the middle Yangtze River basin may experience the opposite trend. The flood risk is expected to increase in spring, summer, and autumn, along with heightened drought risk in winter, summer, and autumn. Southern China would face greater flood risk, while the central Yangtze River basin would face intensified drought risk, especially in the far future. These findings underscore the influence of different emission scenarios on flood and drought risks, emphasizing the need for proactive measures to enhance climate adaptation in the future.

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