Process-based modeling to reveal spatio-temporal variations of coastal wetland-mediated nutrient removal.

Nutrient pollution intensifies the strain on coastal ecosystems globally. Despite wetlands' significant nutrient removal potential, process-based assessments of nutrient removal in large-scale coastal wetlands face limitations that hinder accurate quantification of water quality improvements. This study proposes a novel quantitative approach by developing a coupled hydrodynamic-water quality-wetland biogeochemical model.

Quantitatively unveiling the role of coastal wetlands in regulating eutrophication and enhancing water environmental capacity.

Human activities have intensified the global challenge of coastal eutrophication. Recently, water resource managers have encountered difficulties in formulating precise pollutant reduction strategies to mitigate coastal eutrophication. Despite the recognized importance of coastal wetlands and pollution sources in influencing coastal nutrient levels, accurately quantifying their impact remains difficult.

Numerical simulation validating of a duck-mouth type marine debris collection device's collection mechanism.

Marine debris (MD) poses a significant threat to global coastal ecosystems around the world, necessitating effective strategies for its collection and removal. As a new type of fixed collection device, the duck-mouth type marine debris collection device (MDCD) consists primarily of two components: a central collection system and floating fences which are positioned at a certain angle and open towards the outer bay located on both sides of it. This paper aims to establish a coupling drift model based on hydrodynamic model to study the performance of duck-mouth type MDCD, verify its effectiveness.