Windows of opportunity for salt marsh vegetation establishment on bare tidal flats: The importance of temporal and spatial variability in hydrodynamic forcing

Understanding the mechanisms limiting and facilitating salt marsh vegetation initial establishment is of widespread importance due to the many valuable services salt marsh ecosystems offer. Salt marsh dynamics have been investigated by many previous studies, but the mechanisms that enable or disable salt marsh initial establishment are still understudied. Recently, the “windows of opportunity” (WoO) concept has been proposed as a framework providing an explanation for the initial establishment of biogeomorphic ecosystems and the role of physical disturbance herein. A WoO is a sufficiently long disturbance‐free period following seedling dispersal, which enables successful establishment. By quantifying the occurrence of WoO, vegetation establishment pattern can be predicted. For simplicity sake and as prove of concept, the original WoO framework considers tidal inundation as the only physical disturbance to salt marsh establishment, whereas the known disturbance from tidal currents and wind waves is ignored. In this study, we incorporate hydrodynamic forcing in the WoO framework. Its spatial and temporal variability is considered explicitly in a salt marsh establishment model. We used this model to explain the observed episodic salt marsh recruitment in the Westerschelde Estuary, Netherlands. Our results reveal that this model can significantly increase the spatial prediction accuracy of salt marsh establishment compared to a model that excludes the hydrodynamic disturbance. Using the better performing model, we further illustrate how tidal flat morphology determines salt marsh establishing elevation and width via hydrodynamic force distribution. Our model thus offers a valuable tool to understand and predict bottlenecks of salt marsh restoration and consequences of changing environmental conditions due to climate change.

[1]  P. Herman,et al.  Seed arrival and persistence at the tidal mudflat: identifying key processes for pioneer seedling establishment in salt marshes , 2014 .

[2]  Marcel J. F. Stive,et al.  Laboratory study on wave dissipation by vegetation in combined current–wave flow , 2014 .

[3]  Peter M. J. Herman,et al.  Critical transitions in disturbance‐driven ecosystems: identifying Windows of Opportunity for recovery , 2014 .

[4]  Giovanni Coco,et al.  Review of wave‐driven sediment resuspension and transport in estuaries , 2014 .

[5]  Kerrylee Rogers,et al.  Mangrove expansion and salt marsh decline at mangrove poleward limits , 2014, Global change biology.

[6]  M. Kirwan,et al.  Tidal wetland stability in the face of human impacts and sea-level rise , 2013, Nature.

[7]  S. Temmerman,et al.  Ecosystem-based coastal defence in the face of global change , 2013, Nature.

[8]  P. Herman,et al.  Cross-shore gradients of physical disturbance in mangroves: implications for seedling establishment , 2013 .

[9]  A. Rinaldo,et al.  Statistical mechanics of wind wave‐induced erosion in shallow tidal basins: Inferences from the Venice Lagoon , 2013 .

[10]  Giulio Mariotti,et al.  Wind waves on a mudflat: The influence of fetch and depth on bed shear stresses , 2013 .

[11]  P. Erftemeijer,et al.  Defining Eco-Morphodynamic Requirements for Rehabilitating Eroding Mangrove-Mud Coasts , 2013, Wetlands.

[12]  C. Friedrichs,et al.  Uniform Bottom Shear Stress and Equilibrium Hyposometry of Intertidal Flats , 2013 .

[13]  Chen Wang,et al.  Does biogeomorphic feedback lead to abrupt shifts between alternative landscape states?: An empirical study on intertidal flats and marshes , 2013 .

[14]  N. Gratiot,et al.  Coastal engineering and large-scale mangrove destruction in Guyana, South America: Averting an environmental catastrophe in the making , 2012 .

[15]  Gemma L. Harvey,et al.  Understanding system disturbance and ecosystem services in restored saltmarshes: Integrating physical and biogeochemical processes , 2012 .

[16]  E. Booth,et al.  Hydroecological model predictions indicate wetter and more diverse soil water regimes and vegetation types following floodplain restoration , 2012 .

[17]  M. Kirwan,et al.  Feedbacks between inundation, root production, and shoot growth in a rapidly submerging brackish marsh , 2012 .

[18]  D. Friess,et al.  Are all intertidal wetlands naturally created equal? Bottlenecks, thresholds and knowledge gaps to mangrove and saltmarsh ecosystems , 2012, Biological reviews of the Cambridge Philosophical Society.

[19]  Johan van de Koppel,et al.  Numerical models of salt marsh evolution: Ecological, geomorphic, and climatic factors , 2012, Reviews of Geophysics.

[20]  G. Simarro,et al.  Posidonia oceanica and Cymodocea nodosa seedling tolerance to wave exposure , 2011 .

[21]  Peter M. J. Herman,et al.  Windows of opportunity: thresholds to mangrove seedling establishment on tidal flats , 2011 .

[22]  P. Herman,et al.  Abiotic Factors Governing the Establishment and Expansion of Two Salt Marsh Plants in the Yangtze Estuary, China , 2011, Wetlands.

[23]  L. Alexander,et al.  Reanalysis suggests long‐term upward trends in European storminess since 1871 , 2011 .

[24]  Luca Carniello,et al.  Modeling wind waves and tidal flows in shallow micro-tidal basins , 2011 .

[25]  Bregje K. van Wesenbeeck,et al.  How ecological engineering can serve in coastal protection , 2011 .

[26]  S. Temmerman,et al.  Limits on the adaptability of coastal marshes to rising sea level , 2010 .

[27]  David P. Callaghan,et al.  Hydrodynamic forcing on salt-marsh development: Distinguishing the relative importance of waves and tidal flows , 2010 .

[28]  C. Friedrichs,et al.  Spatial Trends in Tidal Flat Shape and Associated Environmental Parameters in South San Francisco Bay , 2010 .

[29]  Giulio Mariotti,et al.  A numerical model for the coupled long‐term evolution of salt marshes and tidal flats , 2010 .

[30]  Andrew D Richardson,et al.  Near-surface remote sensing of spatial and temporal variation in canopy phenology. , 2009, Ecological applications : a publication of the Ecological Society of America.

[31]  Stijn Temmerman,et al.  Effects of shoot stiffness, shoot size and current velocity on scouring sediment from around seedlings and propagules , 2009 .

[32]  Simon M. Mudd,et al.  Impact of dynamic feedbacks between sedimentation, sea-level rise, and biomass production on near-surface marsh stratigraphy and carbon accumulation , 2009 .

[33]  H. Viles,et al.  Biogeomorphological disturbance regimes: progress in linking ecological and geomorphological systems , 2008 .

[34]  Robert R. Christian,et al.  Consequences of Climate Change on the Ecogeomorphology of Coastal Wetlands , 2008 .

[35]  Peter M. J. Herman,et al.  Spatial patterns, rates and mechanisms of saltmarsh cycles (Westerschelde, the Netherlands) , 2008 .

[36]  Carrie V. Kappel,et al.  Coastal Ecosystem-Based Management with Nonlinear Ecological Functions and Values , 2008, Science.

[37]  S. Temmerman,et al.  Vegetation causes channel erosion in a tidal landscape , 2007 .

[38]  Andrea Rinaldo,et al.  Biologically‐controlled multiple equilibria of tidal landforms and the fate of the Venice lagoon , 2007 .

[39]  L. Rijn Unified view of sediment transport by currents and waves. I: Initiation of motion, bed roughness, and bed-load transport , 2007 .

[40]  G. Coco,et al.  Sediment transport on an estuarine intertidal flat: Measurements and conceptual model of waves, rainfall and exchanges with a tidal creek , 2007 .

[41]  C. C. Watson,et al.  Restoration of the Mississippi Delta: Lessons from Hurricanes Katrina and Rita , 2007, Science.

[42]  T. Bailey Spatial Analysis: A Guide for Ecologists , 2006 .

[43]  Luca Carniello,et al.  Critical bifurcation of shallow microtidal landforms in tidal flats and salt marshes. , 2006, Proceedings of the National Academy of Sciences of the United States of America.

[44]  Luca Carniello,et al.  A combined wind wave–tidal model for the Venice lagoon, Italy , 2004 .

[45]  Johan van de Koppel,et al.  Self‐Organization and Vegetation Collapse in Salt Marsh Ecosystems , 2004, The American Naturalist.

[46]  Jerald B. Johnson,et al.  Model selection in ecology and evolution. , 2004, Trends in ecology & evolution.

[47]  S. Lentz,et al.  Classical tidal harmonic analysis including error estimates in MATLAB using T_TIDE , 2002 .

[48]  P. V. Sundareshwar,et al.  RESPONSES OF COASTAL WETLANDS TO RISING SEA LEVEL , 2002 .

[49]  Cédric Bacher,et al.  Characterization of intertidal flat hydrodynamics , 2000 .

[50]  Richard J. S. Whitehouse,et al.  Investigation using simple mathematical models of the effect of tidal currents and waves on the profile shape of intertidal mudflats , 2000 .

[51]  N. Booij,et al.  A third-generation wave model for coastal regions-1 , 1999 .

[52]  J. Allen Salt-marsh growth and fluctuating sea level: implications of a simulation model for Flandrian coastal stratigraphy and peat-based sea-level curves , 1995 .

[53]  D. Reed The response of coastal marshes to sea‐level rise: Survival or submergence? , 1995 .

[54]  W. H. Patrick,et al.  The relationship of smooth cordgrass (Spartina alterniflora) to tidal datums: A review , 1988 .

[55]  Donald R. Cahoon,et al.  Coastal Wetland Vulnerability to Relative Sea-Level Rise: Wetland Elevation Trends and Process Controls , 2006 .

[56]  R. Soulsby Dynamics of marine sands : a manual for practical applications , 1997 .

[57]  T. Barnett,et al.  Measurements of wind-wave growth and swell decay during the Joint North Sea Wave Project (JONSWAP) , 1973 .