Flow resistance at lowland and mountainous rivers

1Afzalimehr, H., 2010. Effect of non‐uniformity of flow on velocity and turbulence intensities over a cobble‐bed. Hydrol. Process., 24, 3, 331–341.Search in Google Scholar

2Afzalimehr, H., Gallichand, J., Jueyi, S.U.I., Bagheri, E., 2011. Field investigation on friction factor in mountainous cobble-bed and boulder-bed rivers. Int. J. Sediment Res., 26, 2, 210–221.Search in Google Scholar

3Afzalimehr, H., Rennie, C.D., 2009. Determination of bed shear stress in gravel-bed rivers using boundary-layer parameters. Hydrol. Sci. J., 54, 1, 147–159.Search in Google Scholar

4Afzalimehr, H., Singh, V.P., Najafabadi, E.F., 2010. Determination of form friction factor. J. Hydrol. Eng., 15, 3, 237–243. Alemi, M., Maia, R., 2022. A three-step approach for bias adjustment of satellite-based daily precipitation data. In: Proc. 39th IAHR World Congress, International Association for Hydro-Environment Engineering and Research, June 19–24, Granada, Spain.Search in Google Scholar

5Allen, J., Somerfield, P., Gilbert, F., 2007. Quantifying uncertainty in high‐resolution coupled hydrodynamic‐ecosystem models. J. Mar. Syst., 64, 1–4, 3–14.Search in Google Scholar

6Amiri, M.J., Bahrami, M., Hamidifar, H., Eslamian, S., 2016. Modification of furrow Manning’s roughness coefficient estimation by finite difference technique under surge and continuous flow. Int. J. Hydrol. Sci. Technol., 6, 3, 226–237.Search in Google Scholar

7Box, W., Järvelä, J., Västilä, K., 2021. Flow resistance of floodplain vegetation mixtures for modeling river flows. J. Hydrol., 601, 126593. https://doi.org/10.1016/j.jhydrol.2021.126593Search in Google Scholar

8Cai, R., Zhang, H., Zhang, Y., Zhang, L., Huang, H., 2020. Flow resistance equation in sand-bed rivers and its practical application in the Yellow River. Water, 12, 3, 727. https://doi.org/10.3390/w12030727Search in Google Scholar

9Champion, P.D., Tanner, C.C., 2000. Seasonality of macro-phytes and interaction with flow in a New Zealand lowland stream. Hydrobiologia, 441, 1, 1–12.Search in Google Scholar

10D’Agostino, V., Michelini, T., 2015. On kinematics and flow velocity prediction in step‐pool channels. Water Resour. Res., 51, 6, 4650–4667.Search in Google Scholar

11Dey, S., 2014. Fluvial Hydrodynamics. Hydrodynamic and Sediment Transport Phenomena. Springer, 687 p.Search in Google Scholar

12Dingman, S.L., 2009. Fluvial Hydraulics. Oxford University Press.Search in Google Scholar

13Diplas, P., Chatanantavet, P., Almedeij, J., 2016. Streambed structure, stream power, and bed load transport: A unified outlook for gravel-bed and bedrock streams. In: Proc. Int. Conf. on fluvial hydraulics (river flow 2016), July 11–14, St. Louis, USA.Search in Google Scholar

14Dodangeh, E., Afzalimehr, H., 2022. Incipient motion of sediment particles in the presence of bed forms under decelerating and accelerating flows. J. Hydrol. Hydromech, 70, 1, 89–102.Search in Google Scholar

15Einstein, H.A., Barbarossa, N.L., 1952. River channel roughness. Trans. Am. Soc. Civil Eng., 117, 1, 1121–1132.Search in Google Scholar

16Eslamian, S., Okhravi, S., Eslamian, F., 2019. Constructed Wet-land: Hydraulic Design. Taylor and Francis Group, CRC Press, Boca Raton FL, USA, 88 p.Search in Google Scholar

17Ferguson, R.I., Sharma, B.P., Hardy, R.J., Hodge, R.A., Warburton, J., 2017. Flow resistance and hydraulic geometry in contrasting reaches of a bedrock channel. Water Resour. Res., 53, 3, 2278–2293.Search in Google Scholar

18Ferguson, R., 2007. Flow resistance equations for gravel‐and boulder‐bed streams. Water Resour. Res., 43, 5. https://doi.org/10.1029/2006WR005422Search in Google Scholar

19Ferguson, R., 2010. Time to abandon the Manning equation? Earth Surf. Process. Landf., 35, 15, 1873–1876.Search in Google Scholar

20Ferguson, R.I., Lewin, J., Hardy, R.J., 2022. Fluvial processes and landforms. Geol. Soc. Lond. Mem., 58, 257–270.Search in Google Scholar

21Ferro, V., 2018a. Assessing flow resistance in gravel bed channels by dimensional analysis and self‐similarity. Catena, 169, 119–127.Search in Google Scholar

22Ferro, V., 2018b. Flow resistance law under equilibrium bed‐ load transport condition. Flow Meas. Instrum., 64, 1–8.Search in Google Scholar

23Franklin, P., Dunbar, M., Whitehead, P., 2008. Flow controls on lowland river macrophytes: a review. Sci. Total Environ., 400, 1–3, 369–378.Search in Google Scholar

24Garcia, M., Parker, G., 1993. Experiments on the entrainment of sediment into suspension by a dense bottom current. J. Geophys. Res. Oceans, 98, C3, 4793–4807.Search in Google Scholar

25García, M.H., 2008. Sediment transport and morphodynamics. In: García, M.H. (Ed.): Sedimentation Engineering: Processes, Measurements, Modeling, and Practice. Manuals and reports on engineering practice number 110. American Society of Civil Engineers, Reston, pp. 21–163.Search in Google Scholar

26Hodge, R.A., Voepel, H., Leyland, J., Sear, D.A., Ahmed, S., 2020. X-ray computed tomography reveals that grain protrusion controls critical shear stress for entrainment of fluvial gravels. Geology, 48, 2, 149–153.Search in Google Scholar

27Julien, P.Y., 1995. Erosion and Sedimentation. Cambridge University Press. Melbourne, USA.Search in Google Scholar

28Malakar, P., Das, R., 2021. Relative role of sediment entrainments on log-law parameters of longitudinal velocity distributions in mobile bed flows. J. Hydrol. Hydromech, 69, 3, 243–254.Search in Google Scholar

29McKie, C.W., Juez, C., Plumb, B.D., Annable, W.K., Franca, M.J., 2021. How large immobile sediments in gravel bed rivers impact sediment transport and bed morphology. J. Hydraul. Eng., 147, 2, 04020096. https://doi.org/10.1061/(ASCE)HY.1943-7900.0001842Search in Google Scholar

30Mendicino, G., Colosimo, F., 2019. Analysis of flow resistance equations in gravel‐bed rivers with intermittent regimes: Calabrian fiumare data set. Water Resour. Res., 55, 8, 7294–7319.Search in Google Scholar

31Mewis, P., 2021. Estimation of vegetation-induced flow resistance for hydraulic computations using airborne laser scanning data. Water, 13, 13, 1864. https://doi.org/10.3390/w13131864Search in Google Scholar

32Moriasi, D., Gitau, M., Pai, N., Daggupati, P., 2015. Hydrologic and water quality models: Performance measures and evaluation criteria. Trans. ASABE (American Society of Agricultural and Biological Engineers), 58, 6, 1763–1785.Search in Google Scholar

33Naderi, M., Afzalimehr, H., Dehghan, A., Darban, N., Nazari-Sharabian, M., Karakouzian, M., 2022. Field study of three-parameter flow resistance model in rivers with vegetation patch. Fluids, 7, 8, 284. https://doi.org/10.3390/fluids7080284Search in Google Scholar

34Namaee, M.R., Sui, J., Whitcombe, T., 2017. A revisit of different models for flow resistance in gravel-bed rivers and hydraulic flumes. Int. J. River Basin Manage., 15, 3, 277–286.Search in Google Scholar

35Nezu, I., Nakagawa, H., 1993. Turbulence in Open Channel Flows. IAHR Monograph, A.A. Balkema, Rotterdam. Nicosia, A., Carollo, F.G., Ferro, V., 2023. Evaluating the influence of boulder arrangement on flow resistance in gravel-bed channels. J. Hydrol., 621, 129610. https://doi.org/10.1016/j.jhydrol.2023.129610Search in Google Scholar

36Okhravi, S., 2022. The use of the Manning equation is not safe for different river types. What are the alternatives? In: Proc. 34^th Conference of Young Hydrologists Professionals in Water Sciences. International Hydrological Program of UNESCO, Slovak Hydrometeorological Institute, November 10, Bratislava, Slovakia.Search in Google Scholar

37Okhravi, S., Gohari, S., 2020. Form friction factor of armored riverbeds. Can. J. Civ. Eng., 47, 11, 1238–1248.Search in Google Scholar

38Okhravi, S., Schügerl, R., Velísková, Y., 2022a. Flow resistance in lowland rivers impacted by distributed aquatic vegetation. Water Resour. Manage., 36, 2257–2273.Search in Google Scholar

39Okhravi, S., Sokáč, M., Velísková, Y., 2022b. Three-dimensional numerical modeling of water temperature distribution in the Rozgrund Reservoir, Slovakia. Acta Hydrologica Slovaca, 23, 2, 305–316.Search in Google Scholar

40Okhravi. S., Eslamian, S., 2022. Form resistance prediction in gravel-bed rivers. In: Eslamian, S., Eslamian, F. (Eds.): Flood Handbook. Taylor and Francis Group, CRC Press, pp. 125–138.Search in Google Scholar

41Powell, D.M., 2014. Flow resistance in gravel-bed rivers: Progress in research. Earth Sci. Rev., 136, 301–338.Search in Google Scholar

42Rickenmann, D., Recking, A., 2011. Evaluation of flow resistance in gravel-bed rivers through a large field data set. Water Re-sour. Res., 47, 7. https://doi.org/10.1029/2010WR009793Search in Google Scholar

43Schügerl, R., Velísková, Y., Sočuvka, V., Dulovičová, R., 2020. Effect of aquatic vegetation on Manning roughness coefficient value-case study at the Šúrsky channel. Acta Hydrologica Slovaca, 21, 1, 123–129.Search in Google Scholar

44Shields, A., 1936. Application of similarity principles and turbulence research to bedload movement. PhD Thesis. Berlin, Germany: Mitteilungen der Preussischen Versuchsanstalt für Wasserbau und Schiffbau, Technischen Hochschule Berlin. (In German.)Search in Google Scholar

45Song, S., Schmalz, B., Fohrer, N., 2014. Simulation and comparison of stream power in-channel and on the floodplain in a German lowland area. J. Hydrol. Hydromech., 62, 2, 133–144.Search in Google Scholar

46Song, S., Schmalz, B., Xu, Y.P., Fohrer, N., 2017. Seasonality of roughness-the indicator of annual river flow resistance condition in a lowland catchment. Water Resour. Manage., 31, 11, 3299–3312.Search in Google Scholar

47Sulaiman, M.S., Sinnakaudan, S.K., Azhari, N.N., Abidin, R.Z., 2017. Behavioral of sediment transport at lowland and mountainous rivers: a special reference to selected Malaysian rivers. Environ. Earth Sci., 76, 7, 300. https://doi.org/10.1007/s12665-017-6620-ySearch in Google Scholar

48Thomas, C., Stamataki, I., Rosselló-Geli, J., 2023. Reconstruction of the 1974 flash flood in Sóller (Mallorca) using a hydraulic 1D/2D model. J. Hydrol. Hydromech, 71, 1, 49–63.Search in Google Scholar

49Van Rijn, L.C., 1984. Sediment transport, part III: bed forms and alluvial roughness. J. Hydraul. Eng., 110, 12, 1733–1754. Search in Google Scholar

50Vanoni, V.A., Brooks, N.H., 1957. Laboratory studies of the roughness and suspended load of alluvial streams (No. 11). US Army Engineer Division, Missouri River.Search in Google Scholar

51Venditti, J.G., 2013. Bedforms in sand-bedded rivers. In: Bishop, M.P., Shroder, J.F. (Eds.): Treatise on Geomorphology. Vol 3. Remote Sensing and GIScience in Geomorphology. Elsevier Academic Press.Search in Google Scholar

52Willemsen, P.W., Horstman, E.M., Bouma, T.J., Baptist, M.J., Van Puijenbroek, M.E., Borsje, B.W., 2022. Facilitating salt marsh restoration: the importance of event-based bed level dynamics and seasonal trends in bed level change. Front. Mar. Sci., 8, 793235. https://doi.org/10.3389/fmars.2021.793235Search in Google Scholar

53Willmott, C.J., Robeson, S.M., Matsuura, K., 2012. A refined index of model performance. Int. J. Climatol, 32, 13, 2088–2094.Search in Google Scholar

54Wright, S., Parker, G., 2004. Flow resistance and suspended load in sand-bed rivers: simplified stratification model. J. Hydraul. Eng., 130, 8, 796–805.Search in Google Scholar

55Yalin, M.S., 1972. Mechanics of Sediment Transport. 1st Ed. Pergamon Press, Oxford, Toronto.Search in Google Scholar

56Yang, S.Q., Tan, S.K., Lim, S.Y., 2005. Flow resistance and bed form geometry in a wide alluvial channel. Water Resour. Res., 41, 9. https://doi.org/10.1029/2005WR004211Search in Google Scholar

57Yen, B.C., 2002. Open channel flow resistance. J. Hydraul. Eng., 128, 20–39.Search in Google Scholar

58Zomer, J.Y., Vermeulen, B., Hoitink, A.J., 2023. Coexistence of two dune scales in a lowland river. Earth Surf. Dynam. Discuss. (Preprint). https://doi.org/10.5194/esurf-2023-12. (In review)Search in Google Scholar

59Zwolenik, M., Michalec, B., 2023. Effect of water surface slope and friction slope on the value of the estimated Manning’s roughness coefficient in gravel-bed streams. J. Hydrol. Hydromech, 71, 1, 80–90.Search in Google Scholar