Abstract
Changes in the climate and landcover are the two most important factors that influence terrestrial hydrological systems. Today, watershed-scale hydrological models are widely used to estimate the individual impacts of changes in the climate and landcover on watershed hydrology. The Minjiang river watershed is an ecologically and economically important, humid, subtropical watershed, located in south-eastern China. Several studies are available on the impacts of recent climate change on the watershed; however, no efforts have been made to separate the individual contributions of climate and landcover changes. This study is an attempt to separate the individual impacts of recent (1989–2018) climate and landcover changes on some of the important hydrological components of the watershed, and highlight the most influential changes in climate parameters and landcover classes. A calibrated soil and water assessment tool (SWAT) was employed for the study. The outcomes revealed that, during the study period, water yield decreased by 6.76%, while evapotranspiration, surface runoff and sediment yield increased by 1.08%, 24.11% and 33.85% respectively. The relative contribution of climate change to landcover change for the decrease in the water yield was 95%, while its contribution to the increases in evapotranspiration, surface runoff and sediment yield was 56%, 77% and 51%, respectively. The changes in climate parameters that were most likely responsible for changes in ET were increasing solar radiation and temperature and decreasing wind speed, those for changes in the water yield were decreasing autumn precipitation and increasing solar radiation and temperature, those for the increase in surface runoff were increasing summer and one-day maximum precipitation, while those for the increasing sediment yield were increasing winter and one-day maximum precipitation. Similarly, an increase in the croplands at the expense of needle-leaved forests was the landcover change that was most likely responsible for a decrease in the water yield and an increase in ET and sediment yield, while an increase in the amount of urban land at the expense of broadleaved forests and wetlands was the landcover change that was most likely responsible for increasing surface runoff. The findings of the study can provide support for improving management and protection of the watershed in the context of landcover and climate change.
Highlights
A watershed is a complex system that encompasses a variety of subsystems, each with distinct vegetation–biogeochemical–hydrological interactions
The Minjiang river watershed is located between 116◦ 300 and 119◦ 300 E and 25◦ 200 and km2◦
The performance of the model when simulating the sediment loading was affected by the reservoirs, because these artificially managed structures disturb the natural stream flow and limit the amount of sediment that is transported
Summary
A watershed is a complex system that encompasses a variety of subsystems, each with distinct vegetation–biogeochemical–hydrological interactions. Any systematic change in its components produces direct as well as indirect impacts that propagate throughout the system [1]. Climate and landcover are essential components in a watershed system. In response to climate change, the hydrological cycle is expected to alter as increasing temperatures accelerate evaporation [2]. Changes in the climate can cause chronic and periodic water shortages [3]. Climate change is reported to impact the quality, quantity and availability of water. It can alter the flow regime and change nutrient and sediment yield [4]. Changes in the landcover can produce impacts on the quality and quantity of water and surface runoff [5]
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