Original Article
Bae, I. 2024. Reach-scale analysis of flow resistance due to woody riparian vegetation patches. University of Science and Technology, Korea. (in Korean)
Baptist, M.J., Babovic, V., Rodríguez Uthurburu, J., Keijzer, M., Uittenbogaard, R.E., Mynett, A. and Verwey, A. 2007. On inducing equations for vegetation resistance. Journal of Hydraulic Research 45(4): 435-450.
10.1080/00221686.2007.9521778Bae, I., Ji, U., Järvelä, J. and Västilä, K. 2024. Blockage effect of emergent riparian vegetation patches on river flow. Journal of Hydrology 635: 131197.
10.1016/j.jhydrol.2024.131197Champion, P.D. and Tanner, C.C. 2000. Seasonality of macrophytes and interaction with flow in a New Zealand lowland stream. Hydrobiologia 441: 1-12.
10.1023/A:1017517303221Cornacchia, L., Folkard, A., Davies, G., Grabowski, R. C., van de Koppel, J., van der Wal, D., Wharton, G., Puijalon, S. and Bouma, T.J. 2019. Plants face the flow in V formation: A study of plant patch alignment in streams. Limnology and Oceanography 64(3): 1087-1102.
10.1002/lno.11099Cornacchia, L., Lapetoule, G., Licci, S., Basquin, H. and Puijalon, S. 2023. How to build vegetation patches in hydraulic studies: A hydrodynamic-ecological perspective on a biological object. Journal of Ecohydraulics 8(2): 105-120.
10.1080/24705357.2023.2176375Erickson, H.E., Soto, P., Johnson, D.W., Roath, B. and Hunsaker, C. 2005. Effects of vegetation patches on soil nutrient pools and fluxes within a mixed-conifer forest. Forest Science 51(3): 211-220.
10.1093/forestscience/51.3.211Hwang, S.D., Choi, S.H., Lee, S.J. and Jang, C.L. 2013. Long-term riverbed change simulation and analisys in the river. Spatial Information Research 21(5): 1-6.
10.12672/ksis.2013.21.5.001Järvelä, J. 2002. Flow resistance of flexible and stiff vegetation: A flume study with natural plants. Journal of Hydrology 269(1-2): 44-54.
10.1016/S0022-1694(02)00193-2Ji, U., Järvelä, J., Västilä, K. and Bae, I. 2023a. Experimentation and modeling of reach-scale vegetative flow resistance due to willow patches. Journal of Hydraulic Engineering 149(7): 04023018.
10.1061/JHEND8.HYENG-13293Ji, U., Järvelä, J., Västilä, K. and Bae, I. 2023b. Experimentation and Modeling of Reach-Scale Vegetative Flow Resistance due to Willow Patches. Journal of Hydraulic Engineering 149(7): 04023018.
10.1061/JHEND8.HYENG-13293Kazem, M., Afzalimehr, H. and Sui, J. 2021. Formation of coherent flow structures beyond vegetation patches in channel. Water 13(20): 2812.
10.3390/w13202812Kim, W. and Kim, S. 2019. Analysis of the riparian vegetation expansion in middle size rivers in Korea. Journal of Korea Water Resources Association, 52: 875-885. (in Korean)
Kleeberg, A., Köhler, J., Sukhodolova, T. and Sukhodolov, A. 2010. Effects of aquatic macrophytes on organic matter deposition, resuspension and phosphorus entrainment in a lowland river. Freshwater Biology 55(2): 326-345.
10.1111/j.1365-2427.2009.02277.xLee, C., Choi, H., Kim, D., van Oorschot, M., Penning, E. and Geerling, G. 2023. Bio‐geomorphic alteration through shifting flow regime in a modified monsoonal river system in Korea. River Research and Applications 39(8): 1639-1651.
10.1002/rra.4169Lee, C., Kim, D.G., Ji, U. and Kim, J. 2019. Dataset of long-term monitoring on the change in hydrology, channel morphology, landscape and vegetation along the Naeseong stream (I). Ecology and Resilient Infrastructure 6(1): 23-33. (in Korean)
Lee, S.H., Ock, K.Y. and Choi, J.K. 2008. A Study on the Expansion Process of Vegetation on Sand-bars in Fluvial Meandering Stream. Korean Society of Environment and Ecology 22(6): 658-665. (in Korean)
Li, M., Yan, Q., Li, G., Yi, M. and Li, J. 2022. Spatio-temporal changes of vegetation cover and its influencing factors in northeast China from 2000 to 2021. Remote Sensing 14(22): 5720.
10.3390/rs14225720Licci, S., Marmonier, P., Wharton, G., Delolme, C., Mermillod-Blondin, F., Simon, L., Vallier, F., Bouma, T.J. and Puijalon, S. 2022. Scale-dependent effects of vegetation on flow velocity and biogeochemical conditions in aquatic systems. Science of the Total Environment 833: 155123.
10.1016/j.scitotenv.2022.155123Liu, C. and Shan, Y. 2022. Impact of an emergent model vegetation patch on flow adjustment and velocity. Proceedings of the Institution of Civil Engineers-Water Management 175(2): 55-66.
10.1680/jwama.20.00108Madsen, J.D., Chambers, P.A., James, W.F., Koch, E.W. and Westlake, D.F. 2001. The interaction between water movement, sediment dynamics and submersed macrophytes. Hydrobiologia 444: 71-84.
10.1023/A:1017520800568Naden, P., Rameshwaran, P., Mountford, O. and Robertson, C. 2006. The influence of macrophyte growth, typical of eutrophic conditions, on river flow velocities and turbulence production. Hydrological Processes: An International Journal 20(18): 3915-3938.
10.1002/hyp.6165Naiman, R.J., Decamps, H. and Pollock, M. 1993. The role of riparian corridors in maintaining regional biodiversity. Ecological Applications 3(2): 209-212.
10.2307/1941822Nepf, H.M. 2012. Flow and transport in regions with aquatic vegetation. Annual Review of Fluid Mechanics 44(1): 123-142.
10.1146/annurev-fluid-120710-101048Nikora, V., Larned, S., Nikora, N., Debnath, K., Cooper, G. and Reid, M. 2008. Hydraulic Resistance due to Aquatic Vegetation in Small Streams: Field Study. Journal of Hydraulic Engineering 134(9): 1326-1332.
10.1061/(ASCE)0733-9429(2008)134:9(1326)Park, B.J., Jang, C.L., Lee, S.H. and Jung, K.D. 2008. A Study on the Sandbar and Vegetation Area Alteration at the Downstream of Dam. Journal of Korea Water Resources Association 41(12): 1163-1172. (in Korean)
10.3741/JKWRA.2008.41.12.1163Pickett, S.T., Burch, W.R., Dalton, S.E., Foresman, T.W., Grove, J.M. and Rowntree, R. 1997. A conceptual framework for the study of human ecosystems in urban areas. Urban Ecosystems 1: 185-199.
10.1023/A:1018531712889Pietri, L., Petroff, A., Amielh, M. and Anselmet, F. 2009. Turbulence characteristics within sparse and dense canopies. Environmental Fluid Mechanics 9(3): 297-320.
10.1007/s10652-009-9131-xSchoelynck, J., Creëlle, S., Buis, K., De Mulder, T., Emsens, W.-J., Hein, T., Meire, D., Meire, P., Okruszko, T. and Preiner, S. 2018. What is a macrophyte patch? Patch identification in aquatic ecosystems and guidelines for consistent delineation. Ecohydrology & Hydrobiology 18(1): 1-9.
10.1016/j.ecohyd.2017.10.005Schoelynck, J., Müller, F., Vandevenne, F., Bal, K., Barão, L., Smis, A., Opdekamp, W., Meire, P. and Struyf, E. 2014. Silicon-vegetation interaction in multiple ecosystems: A review. Journal of Vegetation Science 25(1): 301-313.
10.1111/jvs.12055Van Dijk, W., Teske, R., Van de Lageweg, W. and Kleinhans, M. 2013. Effects of vegetation distribution on experimental river channel dynamics. Water Resources Research 49(11): 7558-7574.
10.1002/2013WR013574Västilä, K. and Järvelä, J. 2014. Modeling the flow resistance of woody vegetation using physically based properties of the foliage and stem, Water Resources Research 50(1): 229-245.
10.1002/2013WR013819- Publisher :Korean Society of Ecology and Infrastructure Engineering
- Publisher(Ko) :응용생태공학회
- Journal Title :Ecology and Resilient Infrastructure
- Journal Title(Ko) :응용생태공학회 논문집
- Volume : 11
- No :3
- Pages :90-99
- Received Date : 2024-09-10
- Revised Date : 2024-09-26
- Accepted Date : 2024-09-27
- DOI :https://doi.org/10.17820/eri.2024.11.3.090