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06.06.2023 | Original Paper

Interspecific competition of Hygrophila genus at different flow rates in artificial channels

verfasst von: Shiang-Yuarn Chen

Erschienen in: Landscape and Ecological Engineering | Ausgabe 4/2023

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Abstract

Vegetation has been shown to be a dominant factor that affects flow capacity and flow conditions. Most empirical studies of the effects of plants on flow have been conducted in artificial channels, using plastic leaves or rigid cylindrical materials, and they have focused on hydraulic effects. Relatively few studies have examined plant-induced flow resistance in open channels, the morphological adaptation of plants to flow conditions, or differences in plant responses to competitive environments. In this study, the native species Hygrophila genus were chosen as planting materials to investigate the effects of inter-specific competition and compare responses to flow resistance between two aquatic macrophytes at different flow rates. It was found that the average number of green leaves, leaf area, ratio of vascular bundle area to cross-section area, plant height and root length of Hygrophila pogonocalyx were higher than those of the Hygrophila salicifolia. However, the survival rate of Hygrophila salicifolia was higher than that of Hygrophila pogonocalyx in both the control and experimental groups. When facing a competitive environment, the response mechanism of Hygrophila salicifolia is to reduce plant height, root length and stem section area more significantly than Hygrophila pogonocalyx. Experimental results suggest that the average root length of Hygrophila is reduced for the purpose of adapting to changes in the flow rate when the plants are mixed. Overall, flow-resistance adaptation of Hygrophila was different for both species when mixed species were planted than when species were planted alone, which demonstrates the presence of inter-specific competition.

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Literatur
Zurück zum Zitat Anderson RJ, Bledsoe BP, Hession WC (2004) Width of streams and rivers in response to vegetation, bank material, and other factors. J Am Water Resour Assoc 40:1159–1172CrossRef Anderson RJ, Bledsoe BP, Hession WC (2004) Width of streams and rivers in response to vegetation, bank material, and other factors. J Am Water Resour Assoc 40:1159–1172CrossRef
Zurück zum Zitat Asaeda T, Fujino T, Manatunge J (2005) Morphological adaptations of emergent plants to water flow: a case study with Typha angustifolia, Zizania latifolia and Phragmites australis. Freshw Biol 50:1991–2001CrossRef Asaeda T, Fujino T, Manatunge J (2005) Morphological adaptations of emergent plants to water flow: a case study with Typha angustifolia, Zizania latifolia and Phragmites australis. Freshw Biol 50:1991–2001CrossRef
Zurück zum Zitat Atapaththu KSS, Asaeda T (2014) Growth and stress responses of Nuttall’s waterweed Elodea nuttallii (Planch) St John to water movements. Hydrobiologia 747:217–233CrossRef Atapaththu KSS, Asaeda T (2014) Growth and stress responses of Nuttall’s waterweed Elodea nuttallii (Planch) St John to water movements. Hydrobiologia 747:217–233CrossRef
Zurück zum Zitat Atapaththu KSS, Miyagi A, Atsuzawa K, Kawai-Yamada M, Asaeda T (2015) Effects of water turbulence on variations in cell ultrastructure and metabolism of amino acids in the submersed macrophyte, Elodea nuttallii (Planch.) H. St John Plant Biol 17:997–1004CrossRef Atapaththu KSS, Miyagi A, Atsuzawa K, Kawai-Yamada M, Asaeda T (2015) Effects of water turbulence on variations in cell ultrastructure and metabolism of amino acids in the submersed macrophyte, Elodea nuttallii (Planch.) H. St John Plant Biol 17:997–1004CrossRef
Zurück zum Zitat Biehle G, Speck T, Spatz HC (1998) Hydrodynamics and Biomechanics of the Submerged Water Moss Fontinalis antipyretica—a comparison of specimens from habitats with different flow velocities. Bot Acta 111:42–50CrossRef Biehle G, Speck T, Spatz HC (1998) Hydrodynamics and Biomechanics of the Submerged Water Moss Fontinalis antipyretica—a comparison of specimens from habitats with different flow velocities. Bot Acta 111:42–50CrossRef
Zurück zum Zitat Chen SY (2017) Flow resistance mechanism adaptations of rigid-stemmed aquatic macrophytes in simulated water channels. Landsc Ecol Eng 13:157–167CrossRef Chen SY (2017) Flow resistance mechanism adaptations of rigid-stemmed aquatic macrophytes in simulated water channels. Landsc Ecol Eng 13:157–167CrossRef
Zurück zum Zitat Chen SY, Lin JY (2011) Flow resistance adaptation of aquatic macrophytes under different flow velocities. Environ Eng Sci 28:373–383CrossRef Chen SY, Lin JY (2011) Flow resistance adaptation of aquatic macrophytes under different flow velocities. Environ Eng Sci 28:373–383CrossRef
Zurück zum Zitat Dabney SM, Moore MT, Locke MA (2006) Integrated management of in-field, edge-of-field, and after-field buffers. J Am Water Resour Assoc 42:15–24CrossRef Dabney SM, Moore MT, Locke MA (2006) Integrated management of in-field, edge-of-field, and after-field buffers. J Am Water Resour Assoc 42:15–24CrossRef
Zurück zum Zitat Dijkstra JT, Uittenbogaard RE (2010) Modeling the interaction between flow and highly flexible aquatic vegetation. Water Resou Res 46:W12547CrossRef Dijkstra JT, Uittenbogaard RE (2010) Modeling the interaction between flow and highly flexible aquatic vegetation. Water Resou Res 46:W12547CrossRef
Zurück zum Zitat Green JC (2005) Modelling flow resistance in vegetated streams: review and development of new theory. Hydrol Process 19:1245–1259CrossRef Green JC (2005) Modelling flow resistance in vegetated streams: review and development of new theory. Hydrol Process 19:1245–1259CrossRef
Zurück zum Zitat Greenway DR (1987) Vegetation and slope stability. In: Anderson MG, Richards KS (eds) Slope stability: geotechnical engineering and geomorphology. John Wiley & Sons Press, New York Greenway DR (1987) Vegetation and slope stability. In: Anderson MG, Richards KS (eds) Slope stability: geotechnical engineering and geomorphology. John Wiley & Sons Press, New York
Zurück zum Zitat Huang TC, Boufford DE, Ohashi H, Lowry PP II, Peng CI (eds) (1998) Flora of Taiwan, vol 4. Department of Botany, National Taiwan University, Taipei Huang TC, Boufford DE, Ohashi H, Lowry PP II, Peng CI (eds) (1998) Flora of Taiwan, vol 4. Department of Botany, National Taiwan University, Taipei
Zurück zum Zitat James CS, Birkhead AL, Jordanova AA, Sullivan JJ (2004) Flow resistance of emergent vegetation. J Hydraul Eng 42:390–398CrossRef James CS, Birkhead AL, Jordanova AA, Sullivan JJ (2004) Flow resistance of emergent vegetation. J Hydraul Eng 42:390–398CrossRef
Zurück zum Zitat Järvelä J (2002) Flow resistance of flexible and stiff vegetation: a flume study with natural plants. J Hydrol 269:44–54CrossRef Järvelä J (2002) Flow resistance of flexible and stiff vegetation: a flume study with natural plants. J Hydrol 269:44–54CrossRef
Zurück zum Zitat Järvelä J (2004) Flow resistance in environmental channels: focus on vegetation. Helsinki University of Technology Water Resources Publications, Finland Järvelä J (2004) Flow resistance in environmental channels: focus on vegetation. Helsinki University of Technology Water Resources Publications, Finland
Zurück zum Zitat Koehl MAR (1984) How do benthic organisms withstand moving water? Am Zool 24:57–70CrossRef Koehl MAR (1984) How do benthic organisms withstand moving water? Am Zool 24:57–70CrossRef
Zurück zum Zitat Lewis NK (1997) Use of the discharge-weighted average velocity in studies of the frictional energy loss of stream flow. Earth Surf Proc Land 22:329–336CrossRef Lewis NK (1997) Use of the discharge-weighted average velocity in studies of the frictional energy loss of stream flow. Earth Surf Proc Land 22:329–336CrossRef
Zurück zum Zitat Manz DH, Westhoff DR (1988) Numerical analysis of the effects of aquatic weeds on the performance of irrigation conveyance systems. Can J Civ Eng 15:1–13CrossRef Manz DH, Westhoff DR (1988) Numerical analysis of the effects of aquatic weeds on the performance of irrigation conveyance systems. Can J Civ Eng 15:1–13CrossRef
Zurück zum Zitat Puijalon S, Bornette G (2004) Morphological variation of two taxonomically distant plant species along a natural flow velocity gradient. New Phytol 163:651–660CrossRefPubMed Puijalon S, Bornette G (2004) Morphological variation of two taxonomically distant plant species along a natural flow velocity gradient. New Phytol 163:651–660CrossRefPubMed
Zurück zum Zitat Puijalon S, Bornette G, Sagnes P (2005) Adaptation to increasing hydraulic stress: morphology, hydrodynamics and fitness of two higher aquatic plant species. J Exp Bot 56:777–786CrossRefPubMed Puijalon S, Bornette G, Sagnes P (2005) Adaptation to increasing hydraulic stress: morphology, hydrodynamics and fitness of two higher aquatic plant species. J Exp Bot 56:777–786CrossRefPubMed
Zurück zum Zitat Puijalon S, Léna JP, Rivière N, Champagne JY, Rostan JC, Bornette G (2008) Phenotypic plasticity in response to mechanical stress: hydrodynamic performance and fitness of four aquatic plant species. New Phytol 177:907–917CrossRefPubMed Puijalon S, Léna JP, Rivière N, Champagne JY, Rostan JC, Bornette G (2008) Phenotypic plasticity in response to mechanical stress: hydrodynamic performance and fitness of four aquatic plant species. New Phytol 177:907–917CrossRefPubMed
Zurück zum Zitat Puijalon S, Bouma TJ, Douady CJ, Groenendael JV, Anten NPR, Martel E, Bornette G (2011) Plant resistance to mechanical stress: evidence of an avoidance-tolerance trade-off. New Phytol 191:1141–1149CrossRefPubMed Puijalon S, Bouma TJ, Douady CJ, Groenendael JV, Anten NPR, Martel E, Bornette G (2011) Plant resistance to mechanical stress: evidence of an avoidance-tolerance trade-off. New Phytol 191:1141–1149CrossRefPubMed
Zurück zum Zitat Righetti M, Armanini A (2002) Flow resistance in open channel flows with sparsely distributed bushes. J Hydro 269:55–64CrossRef Righetti M, Armanini A (2002) Flow resistance in open channel flows with sparsely distributed bushes. J Hydro 269:55–64CrossRef
Zurück zum Zitat Rutherford I (2002) The influence of riparian management on stream erosion. In: Lovett S, Price P (eds) Riparian land management technical guidelines, principles of sound management, vol 1. LWRRDC, Canberra Rutherford I (2002) The influence of riparian management on stream erosion. In: Lovett S, Price P (eds) Riparian land management technical guidelines, principles of sound management, vol 1. LWRRDC, Canberra
Zurück zum Zitat Sand-Jensen K (2003) Drag and reconfiguration of freshwater macrophytes. Freshw Biol 48:271–283CrossRef Sand-Jensen K (2003) Drag and reconfiguration of freshwater macrophytes. Freshw Biol 48:271–283CrossRef
Zurück zum Zitat Sand-Jensen K, Pedersen O (1999) Velocity gradients and turbulence around macrophyte stands in streams. Freshw Biol 42:315–328CrossRef Sand-Jensen K, Pedersen O (1999) Velocity gradients and turbulence around macrophyte stands in streams. Freshw Biol 42:315–328CrossRef
Zurück zum Zitat Schutten J, Davy AJ (2000) Predicting the hydraulic forces on submerged macrophytes from current velocity, biomass and morphology. Oecologia 123:445–452CrossRefPubMed Schutten J, Davy AJ (2000) Predicting the hydraulic forces on submerged macrophytes from current velocity, biomass and morphology. Oecologia 123:445–452CrossRefPubMed
Zurück zum Zitat Schutten J, Dainty J, Davy AJ (2005) Root anchorage and its significance for submerged plants in shallow lakes. J Ecol 93:556–571CrossRef Schutten J, Dainty J, Davy AJ (2005) Root anchorage and its significance for submerged plants in shallow lakes. J Ecol 93:556–571CrossRef
Zurück zum Zitat Sculthorpe CD (1967) The biology of aquatic vascular plants. Edward Arnold Press, London Sculthorpe CD (1967) The biology of aquatic vascular plants. Edward Arnold Press, London
Zurück zum Zitat Simon A, Collison AJC (2002) Quantifying the mechanical and hydrologic effects of riparian vegetation on stream-bank stability. Earth Surf Proc Land 27:527–546CrossRef Simon A, Collison AJC (2002) Quantifying the mechanical and hydrologic effects of riparian vegetation on stream-bank stability. Earth Surf Proc Land 27:527–546CrossRef
Zurück zum Zitat Simon A, Pollen N, Langendoen E (2006) Influence of two woody riparian species on critical conditions for streambank stability: upper Truckee River, California. J Am Water Resour Assoc 42:99–113CrossRef Simon A, Pollen N, Langendoen E (2006) Influence of two woody riparian species on critical conditions for streambank stability: upper Truckee River, California. J Am Water Resour Assoc 42:99–113CrossRef
Zurück zum Zitat Singh R, Tiwari AK, Singh GS (2021) Managing riparian zones for river health improvement: an integrated approach. Landsc Ecol Eng 17:195–223CrossRef Singh R, Tiwari AK, Singh GS (2021) Managing riparian zones for river health improvement: an integrated approach. Landsc Ecol Eng 17:195–223CrossRef
Zurück zum Zitat Tsai SH (2000) Plant anatomy. World Bookstore, Taipei Tsai SH (2000) Plant anatomy. World Bookstore, Taipei
Zurück zum Zitat Wilson CAME, Stoesser T, Bates PD, Pinzen B (2003) Open channel flow through different forms of submerged flexible vegetation. J Hydraul Eng 129:847–853CrossRef Wilson CAME, Stoesser T, Bates PD, Pinzen B (2003) Open channel flow through different forms of submerged flexible vegetation. J Hydraul Eng 129:847–853CrossRef
Zurück zum Zitat Wu FC, Shen HW, Chou YJ (1999) Variation of roughness coefficients for unsubmerged and submerged vegetation. J Hydraul Eng 125:934–942CrossRef Wu FC, Shen HW, Chou YJ (1999) Variation of roughness coefficients for unsubmerged and submerged vegetation. J Hydraul Eng 125:934–942CrossRef
Zurück zum Zitat Wynn T, Mostaghimi S (2006) The effects of vegetation and soil type on streambank erosion, southwestern Virginia, USA. J Am Water Resour Assoc 42:69–82CrossRef Wynn T, Mostaghimi S (2006) The effects of vegetation and soil type on streambank erosion, southwestern Virginia, USA. J Am Water Resour Assoc 42:69–82CrossRef
Metadaten
Titel
Interspecific competition of Hygrophila genus at different flow rates in artificial channels
verfasst von
Shiang-Yuarn Chen
Publikationsdatum
06.06.2023
Verlag
Springer Japan
Erschienen in
Landscape and Ecological Engineering / Ausgabe 4/2023
Print ISSN: 1860-1871
Elektronische ISSN: 1860-188X
DOI
https://doi.org/10.1007/s11355-023-00562-w

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