[1] Xie H., Deng J., Wu Z., Dong J., Wan N., Xiong Z., Li Z., Li Y., Chen L., Lai X.*, 2026,Revisiting the role of small ponds in regulating river water quality in agricultural landscapes: A focus on pond use types and sediment nutrients. Journal of Environmental Management 402, 129086
[2] Cui Y., Shang, M., Xie H.*, Dong J., 2026. How do hydrodynamic conditions and land use drive antibiotic fate in estuarine and bay ecosystems? Journal of Environmental Sciences 160, 27–38.
[3] Xie H., Gu S., Cui Y., Dong J. *, Wang H.*, Guowei F., 2026. Heavier sediment pollution by per- and polyfluoroalkyl substances (PFASs) in tropical coasts compared to temperate regions: an overlooked hotspot. Journal of Environmental Sciences 162, 456–464
[4] Xie H., Shang M., Dong J.*, Li Y., Lai X., 2025. A distributed and process-based model coupling water-sediment-antibiotic interactions to simulate dynamic source-transport-fate of antibiotics at catchment scale. Journal of Hazardous Materials 483, 136681.
[5] Shang M., Dong J., Xie H.*, Li Y., Wan N., Xiong Z., Lai X., 2025. Unraveling transport mechanisms and rainfall event-driven controls on non-point source antibiotic pollution by high-resolution process-based modeling. Journal of Hazardous Materials 495, 139177.
[6] Xie H., Li Y., Shang M., Dong J.*, Tang X., Wan N., Wang Y., Lai X.*, 2025. How do agricultural polders modulate nutrient dynamics under extreme flooding: Insights for water management in lowland areas. Journal of Hydrology: Regional Studies 57, 102136.
[7] Xie H., Shang M., Dong J., Li Y., Wan N., Xiong Z., Lai X.*, 2025. Antibiotic transport requires a renewed focus on baseflow as a critical non-point source pathway. Environmental Pollution 375, 126355.
[8] Xie H.*, Dong J.*, 2024. Three-dimensional perspectives on revisiting the legacy impacts of non-point source phosphorus. Environmental Research Letters 19, 071002.
[9] Dong J., Feng R., Yao Z., Wang J., Wang Y., Wang H., Yan D.*, Cui Y., Xie H.*, Du Y., Xia X., 2024. Layer-specific mechanisms of perfluoroalkyl acid (PFAA) transport and partition in estuarine environments: Unveiling the depth-dependent differences. Journal of Hazardous Materials 473, 134675.
[10] Gu S., Yin J., Shang M., Ke H., Dong J.*, Zhu X., Xie H.*, 2024. Transport, sources, and risks of particulate antibiotics in coastal environments: The crucial role of particles in mud coasts. Marine Pollution Bulletin 209, 117204.
[11] Shang M., Dong J.*, Xie H.*, Wang Y., Du Y., 2023. Source, transport, and fate of perfluoroalkyl acids (PFAAs) in turbid bay environments: Significant roles of suspended sediment and water column stratification. Water Research 243, 120384.
[12] Xie H., Gao T, Wan N., Xiong Z., Dong J., Lin C., Lai X.*, 2022. Controls for multi-temporal patterns of riverine nitrogen and phosphorus export to lake: Implications for catchment management by high-frequency observations. Journal of Environmental Management 320, 115858.
[13] Dong J., Shang M., Feng R., Song X., Yan D., Xie H.*, 2022. Export and risk from antibiotic remobilization from surrounding water to lake in the extreme 2020 Yangtze River basin flooding. Science of The Total Environment 834, 155176.
[14] Dong J., Xie H.*, Feng Ranran, Lai X., Duan H., Xu L., Xia X., 2021. Transport and fate of antibiotics in a typical aqua-agricultural catchment explained by rainfall events: Implications for catchment management. Journal of Environmental Management 293, 112953.
[15] Xie H., Dong J., Shen Z.*, Chen L., Lai X., Qiu J., Wei G., Peng Y., Chen X., 2019. Intra- and inter-event characteristics and controlling factors of agricultural nonpoint source pollution under different types of rainfall-runoff events. Catena 182, 104105.
[16] Xie H., Wei G., Shen Z.*, Dong J., Peng Y., Chen X., 2019. Event-based uncertainty assessment of sediment modeling in a data-scarce catchment. Catena 173, 162–174.
[17] Xie H., Shen Z.*, Chen L., Lai X., Qiu J., Wei G., Dong J., Peng Y., Chen X., 2019. Parameter estimation and uncertainty analysis: a comparison between continuous and event-based modeling of streamflow based on the Hydrological Simulation Program–Fortran (HSPF) model. Water 11(1): 171.
[18] Xie H., Shen, Z.*, Chen, L., Qiu, J., Dong, J., 2017. Time-varying sensitivity analysis of hydrologic and sediment parameters at multiple timescales: Implications for conservation practices. Science of The Total Environment 598, 353–364.
[19] Xie, H., Chen, L.*, Shen, Z., 2015. Assessment of agricultural best management practices using models: Current issues and future perspectives. Water 7, 1088–1108.
[20] 谢晖,邱嘉丽*,董建玮,高田田,赖锡军, 2022. 流域水文模型在面源污染模拟与管控中的应用研究进展. 生态学报 42, 6076–6091.
[21] 谢晖, 董建玮*, 李玉凤, 商美琪, 赖锡军, 2022. 多水塘系统水文连通及其对磷输移影响研究进展. 33, 848–858.
[22] 高田田, 谢晖*, 万能胜, 熊竹阳, 胡正华*, 赖锡军, 2022. 巢湖典型农村流域面源氮磷污染模拟及来源解析. 农业环境科学学报 41, 2428–2438.
