Human activities, such as urban planning, irrigation and agricultural fertilization, can affect terrestrial carbon, nitrogen, and water cycle processes and aquatic ecosystems.
Some human activities lead to water stress, ecological environment damage, including groundwater lateral flow, and the movement of frost and thaw fronts. These changes in turn alter energy balance and water budget, and affect weather, climate, and environment.
"We need a new land surface model to describe these processes," said professor Zhenghui Xie from the Institute of Atmospheric Physics (IAP) of the Chinese Academy of Sciences. "A comprehensive land surface model can not only provide a platform for water-energy simulations, but also contribute to water resources management, environment protection, and sustainable development."
Xie and his team incorporated the schemes of groundwater lateral flow, human water use, soil freeze-thaw front dynamics, riverine nitrogen transport, and urban planning into a land surface model, and thus developed a land surface model CAS-LSM. According to Xie, the current version has improved the descriptions of biogeochemical process and urban modules, compared with the earlier version of this model.
"The new developed model can be applied to the simulation of inland river basins in arid areas to quantitatively evaluate the ecohydrological effects of stream water transfer," Xie said. "Combined with basin simulation and climate system models, CAS-LSM can monitor river water environment. It can also help quantitatively evaluate weather and climate effects of south-to-north water transfer and provide advice for urban planning."
- This press release was originally published on the Chinese Academy of Science Institute of Atmospheric Physics website. It has been edited for style