Coevolution of hydraulic, soil and vegetation processes in estuarine wetlands.
- Autores
- Trivisonno, Franco N.; Rodriguez, Jose F.; Riccardi, Gerardo A.; Saco, Patricia M.; Stenta, Hernan R.
- Año de publicación
- 2014
- Idioma
- inglés
- Tipo de recurso
- documento de conferencia
- Estado
- versión publicada
- Descripción
- Estuarine wetlands of south eastern Australia, typically display a vegetation zonation with a sequence mudflats - mangrove forest - saltmarsh plains from the seaward margin and up the topographic gradient. Estuarine wetlands are among the most productive ecosystems in the world, providing unique habitats for fish and many terrestrial species. They also have a carbon sequestration capacity that surpasess terrestrial forest. Estuarine wetlands respond to sea-level rise by vertical accretion and horizontal landward migration, in order to maintain their position in the tidal frame. In situations in which buffer areas for landward migration are not available, saltmarsh can be lost due to mangrove encroachment. As a result of mangrove invasion associated in part with raising estuary water levels and urbanisation, coastal saltmarsh in parts of south-eastern Australia has been declared an endangered ecological community. Predicting estuarine wetlands response to sea-level rise requires modelling the coevolving dynamics of water flow, soil and vegetation. This paper presents preliminary results of our recently developed numerical model for wetland dynamics in wetlands of the Hunter estuary of NSW. The model simulates continuous tidal inflow into the wetland, and accounts for the effect of varying vegetation types on flow resistance. Coevolution effects appear as vegetation types are updated based on their preference to prevailing hydrodynamic conditions. The model also considers that accretion values vary with vegetation type. Simulations are driven using local information collected over several years, which includes estuary water levels, accretion rates, soil carbon content, flow resistance and vegetation preference to hydraulic conditions. Model results predict further saltmarsh loss under current conditions of moderate increase of estuary water levels.
Fil: School of Engineering, The University of Newcastle, Callaghan 2308, Australia
Fil: Departamento de Hidráulica, Escuela de Ingenieria Civil, Fac. de Cs. Exactas, Ingenieria y Agrimensura, Universidad Nacional de Rosario
Fil: Consejo de Investigaciones de la Universidad Nacional de Rosario - Materia
-
Estuarine wetlands
Coevolution hydraulic soil and vegetation
Hunter estuary - Nivel de accesibilidad
- acceso abierto
- Condiciones de uso
- http://creativecommons.org/publicdomain/zero/1.0/
- Repositorio
.jpg)
- Institución
- Universidad Nacional de Rosario
- OAI Identificador
- oai:rephip.unr.edu.ar:2133/17641
Ver los metadatos del registro completo
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Coevolution of hydraulic, soil and vegetation processes in estuarine wetlands.Trivisonno, Franco N.Rodriguez, Jose F.Riccardi, Gerardo A.Saco, Patricia M.Stenta, Hernan R.Estuarine wetlandsCoevolution hydraulic soil and vegetationHunter estuaryEstuarine wetlands of south eastern Australia, typically display a vegetation zonation with a sequence mudflats - mangrove forest - saltmarsh plains from the seaward margin and up the topographic gradient. Estuarine wetlands are among the most productive ecosystems in the world, providing unique habitats for fish and many terrestrial species. They also have a carbon sequestration capacity that surpasess terrestrial forest. Estuarine wetlands respond to sea-level rise by vertical accretion and horizontal landward migration, in order to maintain their position in the tidal frame. In situations in which buffer areas for landward migration are not available, saltmarsh can be lost due to mangrove encroachment. As a result of mangrove invasion associated in part with raising estuary water levels and urbanisation, coastal saltmarsh in parts of south-eastern Australia has been declared an endangered ecological community. Predicting estuarine wetlands response to sea-level rise requires modelling the coevolving dynamics of water flow, soil and vegetation. This paper presents preliminary results of our recently developed numerical model for wetland dynamics in wetlands of the Hunter estuary of NSW. The model simulates continuous tidal inflow into the wetland, and accounts for the effect of varying vegetation types on flow resistance. Coevolution effects appear as vegetation types are updated based on their preference to prevailing hydrodynamic conditions. The model also considers that accretion values vary with vegetation type. Simulations are driven using local information collected over several years, which includes estuary water levels, accretion rates, soil carbon content, flow resistance and vegetation preference to hydraulic conditions. Model results predict further saltmarsh loss under current conditions of moderate increase of estuary water levels.Fil: School of Engineering, The University of Newcastle, Callaghan 2308, AustraliaFil: Departamento de Hidráulica, Escuela de Ingenieria Civil, Fac. de Cs. Exactas, Ingenieria y Agrimensura, Universidad Nacional de RosarioFil: Consejo de Investigaciones de la Universidad Nacional de RosarioEuropean Geophysical Union2014-04info:eu-repo/semantics/conferenceObjectinfo:eu-repo/semantics/publishedVersionhttp://purl.org/coar/resource_type/c_5794info:ar-repo/semantics/documentoDeConferenciaapplication/pdfapplication/pdfhttp://hdl.handle.net/2133/17641enghttps://meetingorganizer.copernicus.org/EGU2014/EGU2014-2261-2.pdfinfo:eu-repo/semantics/openAccesshttp://creativecommons.org/publicdomain/zero/1.0/Licencia RepHipreponame:RepHipUNR (UNR)instname:Universidad Nacional de Rosario2025-09-04T09:43:28Zoai:rephip.unr.edu.ar:2133/17641instacron:UNRInstitucionalhttps://rephip.unr.edu.ar/Universidad públicaNo correspondehttps://rephip.unr.edu.ar/oai/requestrephip@unr.edu.arArgentinaNo correspondeNo correspondeNo correspondeopendoar:15502025-09-04 09:43:29.007RepHipUNR (UNR) - Universidad Nacional de Rosariofalse |
| dc.title.none.fl_str_mv |
Coevolution of hydraulic, soil and vegetation processes in estuarine wetlands. |
| title |
Coevolution of hydraulic, soil and vegetation processes in estuarine wetlands. |
| spellingShingle |
Coevolution of hydraulic, soil and vegetation processes in estuarine wetlands. Trivisonno, Franco N. Estuarine wetlands Coevolution hydraulic soil and vegetation Hunter estuary |
| title_short |
Coevolution of hydraulic, soil and vegetation processes in estuarine wetlands. |
| title_full |
Coevolution of hydraulic, soil and vegetation processes in estuarine wetlands. |
| title_fullStr |
Coevolution of hydraulic, soil and vegetation processes in estuarine wetlands. |
| title_full_unstemmed |
Coevolution of hydraulic, soil and vegetation processes in estuarine wetlands. |
| title_sort |
Coevolution of hydraulic, soil and vegetation processes in estuarine wetlands. |
| dc.creator.none.fl_str_mv |
Trivisonno, Franco N. Rodriguez, Jose F. Riccardi, Gerardo A. Saco, Patricia M. Stenta, Hernan R. |
| author |
Trivisonno, Franco N. |
| author_facet |
Trivisonno, Franco N. Rodriguez, Jose F. Riccardi, Gerardo A. Saco, Patricia M. Stenta, Hernan R. |
| author_role |
author |
| author2 |
Rodriguez, Jose F. Riccardi, Gerardo A. Saco, Patricia M. Stenta, Hernan R. |
| author2_role |
author author author author |
| dc.subject.none.fl_str_mv |
Estuarine wetlands Coevolution hydraulic soil and vegetation Hunter estuary |
| topic |
Estuarine wetlands Coevolution hydraulic soil and vegetation Hunter estuary |
| dc.description.none.fl_txt_mv |
Estuarine wetlands of south eastern Australia, typically display a vegetation zonation with a sequence mudflats - mangrove forest - saltmarsh plains from the seaward margin and up the topographic gradient. Estuarine wetlands are among the most productive ecosystems in the world, providing unique habitats for fish and many terrestrial species. They also have a carbon sequestration capacity that surpasess terrestrial forest. Estuarine wetlands respond to sea-level rise by vertical accretion and horizontal landward migration, in order to maintain their position in the tidal frame. In situations in which buffer areas for landward migration are not available, saltmarsh can be lost due to mangrove encroachment. As a result of mangrove invasion associated in part with raising estuary water levels and urbanisation, coastal saltmarsh in parts of south-eastern Australia has been declared an endangered ecological community. Predicting estuarine wetlands response to sea-level rise requires modelling the coevolving dynamics of water flow, soil and vegetation. This paper presents preliminary results of our recently developed numerical model for wetland dynamics in wetlands of the Hunter estuary of NSW. The model simulates continuous tidal inflow into the wetland, and accounts for the effect of varying vegetation types on flow resistance. Coevolution effects appear as vegetation types are updated based on their preference to prevailing hydrodynamic conditions. The model also considers that accretion values vary with vegetation type. Simulations are driven using local information collected over several years, which includes estuary water levels, accretion rates, soil carbon content, flow resistance and vegetation preference to hydraulic conditions. Model results predict further saltmarsh loss under current conditions of moderate increase of estuary water levels. Fil: School of Engineering, The University of Newcastle, Callaghan 2308, Australia Fil: Departamento de Hidráulica, Escuela de Ingenieria Civil, Fac. de Cs. Exactas, Ingenieria y Agrimensura, Universidad Nacional de Rosario Fil: Consejo de Investigaciones de la Universidad Nacional de Rosario |
| description |
Estuarine wetlands of south eastern Australia, typically display a vegetation zonation with a sequence mudflats - mangrove forest - saltmarsh plains from the seaward margin and up the topographic gradient. Estuarine wetlands are among the most productive ecosystems in the world, providing unique habitats for fish and many terrestrial species. They also have a carbon sequestration capacity that surpasess terrestrial forest. Estuarine wetlands respond to sea-level rise by vertical accretion and horizontal landward migration, in order to maintain their position in the tidal frame. In situations in which buffer areas for landward migration are not available, saltmarsh can be lost due to mangrove encroachment. As a result of mangrove invasion associated in part with raising estuary water levels and urbanisation, coastal saltmarsh in parts of south-eastern Australia has been declared an endangered ecological community. Predicting estuarine wetlands response to sea-level rise requires modelling the coevolving dynamics of water flow, soil and vegetation. This paper presents preliminary results of our recently developed numerical model for wetland dynamics in wetlands of the Hunter estuary of NSW. The model simulates continuous tidal inflow into the wetland, and accounts for the effect of varying vegetation types on flow resistance. Coevolution effects appear as vegetation types are updated based on their preference to prevailing hydrodynamic conditions. The model also considers that accretion values vary with vegetation type. Simulations are driven using local information collected over several years, which includes estuary water levels, accretion rates, soil carbon content, flow resistance and vegetation preference to hydraulic conditions. Model results predict further saltmarsh loss under current conditions of moderate increase of estuary water levels. |
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2014 |
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2014-04 |
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eng |
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