Access the full text.
Sign up today, get DeepDyve free for 14 days.
V. Prahalad (2014b)
A guide to the plants of Tasmanian saltmarsh wetlands
J. Allen (2000)
Morphodynamics of Holocene salt marshes: a review sketch from the Atlantic and Southern North Sea coasts of EuropeQuaternary Science Reviews, 19
R. H. MacArthur, E. O. Wilson (1967)
The theory of island biography
P. Boon (2017)
Are mangroves in Victoria (south-eastern Australia) already responding to climate change?Marine and Freshwater Research, 68
N. Saintilan, Kerrylee Rogers (2013)
The significance and vulnerability of Australian saltmarshes: implications for management in a changing climateMarine and Freshwater Research, 64
P. Adam (2002)
Saltmarshes in a time of changeEnvironmental Conservation, 29
K. McKee, Kerrylee Rogers, N. Saintilan (2012)
Response of salt marsh and mangrove wetlands to changes in atmospheric CO2, climate, and sea-level, 1
P. Saenger, M. M. Specht, R. L. Specht, V. J. Chapman (1977)
Ecosystems of the world I: Wet coastal ecosystems
T. Minello, R. Zimmerman, R. Medina (1994)
The importance of edge for natant macrofauna in a created salt marshWetlands, 14
K. McKee, K. Rogers, N. Saintilan (2012)
Global change and the function and distribution of wetlands
G. J. Edgar, N. S. Barrett, D. J. Graddon (1999)
A classification of Tasmanian estuaries and assessment of their conservation significance using ecological and physical attributes, population and land use
E. Barbier, S. Hacker, Chris Kennedy, E. Koch, A. Stier, B. Silliman (2011)
The value of estuarine and coastal ecosystem servicesEcological Monographs, 81
Prahalad, Harrison-Day, A. Latinovic, J. Kirkpatrick (2018)
Inventory and monitoring of the vascular plants of Tasmanian saltmarsh wetlands, 140
Rosa Menéndez, A. González‐Megías, Yvonne Collingham, R. Fox, D. Roy, R. Ohlemüller, C. Thomas (2007)
Direct and indirect effects of climate and habitat factors on butterfly diversity.Ecology, 88 3
V. Prahalad, Violet Harrison‐Day, P. McQuillan, C. Creighton (2019)
Expanding fish productivity in Tasmanian saltmarsh wetlands through tidal reconnection and habitat repairMarine and Freshwater Research
Michael Osland, Laura Feher, K. Griffith, K. Cavanaugh, N. Enwright, R. Day, C. Stagg, K. Krauss, R. Howard, J. Grace, Kerrylee Rogers (2017)
Climatic controls on the global distribution, abundance, and species richness of mangrove forestsEcological Monographs, 87
B. Mackey, S. Berry, Tiffany Brown (2007)
Reconciling approaches to biogeographical regionalization: a systematic and generic framework examined with a case study of the Australian continentJournal of Biogeography, 35
S. P. Corney, J. J. Katzfey, J. L. McGregor, M. R. Grose, J. C. Bennett, C. J. White, N. L. Bindoff (2010)
Climate futures for Tasmania: Climate modelling technical report
K. P. Malamud‐Roam, F. P. Malamud‐Roam, E. B. Watson, J. P. Collins, B. L. Ingram (2006)
Terrestrial vertebrates of tidal marshes: Ecology, evolution, and conservation
N. Saintilan (2009)
Biogeography of Australian saltmarsh plantsAustral Ecology, 34
J. P. Doody (2007)
Saltmarsh conservation, management and restoration
N. Saintilan, K. Rogers, J. Kelleway, E. Ens, D. Sloane (2018)
Climate Change Impacts on the Coastal Wetlands of AustraliaWetlands
N. Chrisman (1987)
The accuracy of map overlays: A reassessmentLandscape and Urban Planning, 14
V. Prahalad (2016)
Atlas of coastal saltmarsh wetlands in the Cradle Coast region of Tasmania
(2013)
Commonwealth conservation advice for subtropical and temperate coastal saltmarsh
William DeLuca, Colin Studds, L. Rockwood, P. Marra (2004)
Influence of land use on the integrity of marsh bird communities of Chesapeake Bay, USAWetlands, 24
J. Kelleway, K. Cavanaugh, Kerrylee Rogers, I. Feller, E. Ens, Cheryl Doughty, N. Saintilan (2017)
Review of the ecosystem service implications of mangrove encroachment into salt marshesGlobal Change Biology, 23
P. Adam (1978)
Geographical Variation in British Saltmarsh VegetationJournal of Ecology, 66
Michael Osland, N. Enwright, C. Stagg (2014)
Freshwater availability and coastal wetland foundation species: ecological transitions along a rainfall gradientEcology, 95
Amy Kunza, S. Pennings (2008)
Patterns of Plant Diversity in Georgia and Texas Salt MarshesEstuaries and Coasts, 31
Laura Mogensen, Kerrylee Rogers (2018)
Validation and Comparison of a Model of the Effect of Sea-Level Rise on Coastal WetlandsScientific Reports, 8
C. McOwen, Lauren Weatherdon, J. Bochove, E. Sullivan, S. Blyth, C. Zockler, D. Stanwell-Smith, N. Kingston, Corinne Martin, M. Spalding, S. Fletcher (2017)
A global map of saltmarshesBiodiversity Data Journal
V. Prahalad, C. Sharples, J. Kirkpatrick, Richard Mount (2015)
Is wind-wave fetch exposure related to soft shoreline change in swell-sheltered situations with low terrestrial sediment input?Journal of Coastal Conservation, 19
M. D. Bertness, S. C. Pennings (2000)
Concepts and controversies in tidal marsh ecology
A. Hirzel, G. Lay (2008)
Habitat suitability modelling and niche theoryJournal of Applied Ecology, 45
R. Greenberg, J. Maldonado, S. Droege, M. Mcdonald (2006)
Tidal Marshes: A Global Perspective on the Evolution and Conservation of Their Terrestrial Vertebrates, 56
V. Prahalad, J. Whitehead, A. Latinovic, J. Kirkpatrick (2019)
The creation and conservation effectiveness of State-wide wetlands and waterways and coastal refugia planning overlays for Tasmania, AustraliaLand Use Policy
V. Prahalad, J. Whitehead, A. Latinovic, J. Kirkpatrick (2019)
The creation and conservation effectiveness of a state‐wide wetlands and waterways planning overlay for Tasmania, Australia, 81
Jamie Kirkpatrick, M. Nuñez, K. Bridle, J. Parry, Neil Gibson (2017)
Causes and consequences of variation in snow incidence on the high mountains of Tasmania, 1983–2013Australian Journal of Botany, 65
Diana Stralberg, Matthew Brennan, J. Callaway, Julian Wood, L. Schile, D. Jongsomjit, M. Kelly, V. Parker, Stephen Crooks (2011)
Evaluating Tidal Marsh Sustainability in the Face of Sea-Level Rise: A Hybrid Modeling Approach Applied to San Francisco BayPLoS ONE, 6
ScholarWorks @ UTRGV ScholarWorks @ UTRGV Beyond just sea-level rise: considering macroclimatic drivers Beyond just sea-level rise: considering macroclimatic drivers within coastal wetland vulnerability assessments to climate within coastal wetland vulnerability assessments to climate change change
L. Kriwoken, P. Hedge (2000)
Exotic species and estuaries : managing Spartina anglica in Tasmania, AustraliaOcean & Coastal Management, 43
(1999)
Using latitudinal variation to examine effects of climate on coastal salt marsh pattern and process
E. Mcleod, G. Chmura, S. Bouillon, R. Salm, M. Björk, C. Duarte, C. Lovelock, W. Schlesinger, B. Silliman (2011)
A blueprint for blue carbon: toward an improved understanding of the role of vegetated coastal habitats in sequestering CO2Frontiers in Ecology and the Environment, 9
J. Kirkpatrick, C. Harwood (1983)
Plant communities of Tasmanian wetlandsAustralian Journal of Botany, 31
N. Duke, J. Kovacs, A. Griffiths, L. Preece, D. Hill, P. Oosterzee, Jock Mackenzie, Hailey Morning, D. Burrows (2017)
Large-scale dieback of mangroves in Australia’s Gulf of Carpentaria: a severe ecosystem response, coincidental with an unusually extreme weather eventMarine and Freshwater Research, 68
J. B. Kirkpatrick, J. Glasby (1981)
Saltmarshes in Tasmania
G. P. Quinn, M. J. Keough (2002)
Experimental design and data analysis for biologists
J. Isacch, C. Costa, L. Rodríguez-gallego, D. Conde, M. Escapa, D. Gagliardini, O. Iribarne (2006)
Distribution of saltmarsh plant communities associated with environmental factors along a latitudinal gradient on the south‐west Atlantic coastJournal of Biogeography, 33
Yuri Zharikov, G. Skilleter, N. Loneragan, T. Taranto, Bronwyn Cameron (2005)
Mapping and characterising subtropical estuarine landscapes using aerial photography and GIS for potential application in wildlife conservation and managementBiological Conservation, 125
P. Bridgewater, I. Cresswell (2003)
Identifying biogeographic patterns in Australian saltmarsh and mangal systems: a phytogeographic analysisPhytocoenologia, 33
V. Prahalad, J. Kirkpatrick, R. Mount (2011)
Tasmanian coastal saltmarsh community transitions associated with climate change and relative sea level rise 1975–2009Australian Journal of Botany, 59
A. Guisan, N. E. Zimmermann (2000)
Predictive habitat distribution models in ecology, 135
S. Harris, A. Buchanan, A. Connolly (2001)
One Hundred Islands: The flora of the Outer Furneaux
J. Kelleway, R. J. Williams, P. Laegdsgaard (2009)
Australian saltmarsh ecology
C. Lundquist, R. Bulmer, M. Clark, Jenny Hillman, W. Nelson, C. Norrie, A. Rowden, D. Tracey, J. Hewitt (2017)
Challenges for the conservation of marine small natural featuresBiological Conservation, 211
V. Prahalad (2014)
Human impacts and saltmarsh loss in the Circular Head coast, north-west Tasmania, 1952– 2006: implications for management.Pacific Conservation Biology, 20
M. J. Osland, N. M. Enwright, R. H. Day, C. A. Gabler, C. L. Stagg, J. B. Grace (2016)
Beyond just sea‐level rise: Considering macroclimatic drivers within coastal wetland vulnerability assessments to climate change, 22
W. Howland (1980)
Multispectral aerial photography for wetland vegetation mapping.Photogrammetric Engineering and Remote Sensing, 46
Kerrylee Rogers, P. Boon, S. Branigan, N. Duke, C. Field, J. Fitzsimons, H. Kirkman, Jock Mackenzie, N. Saintilan (2016)
The state of legislation and policy protecting Australia's mangrove and salt marsh and their ecosystem servicesMarine Policy, 72
(2013)
From forest to fjaeldmark: Descriptions of Tasmania's vegetation
M. Bertness, S. Pennings (2002)
Spatial Variation in Process and Pattern in Salt Marsh Plant Communities in Eastern North America
P. Adam (1997)
Absence of creeks and pans in temperate Australian salt marshesMangroves and Salt Marshes, 1
P. Adam (1990)
Saltmarsh ecology
P. Boon, T. Allen, G. Carr, D. Frood, C. Harty, A. McMahon, S. Mathews, N. Rosengren, S. Sinclair, M. White, J. Yugovic (2015)
Coastal wetlands of Victoria, south‐eastern Australia: providing the inventory and condition information needed for their effective management and conservationAquatic Conservation-marine and Freshwater Ecosystems, 25
J. Fariña, Qiang He, B. Silliman, M. Bertness (2018)
Biogeography of salt marsh plant zonation on the Pacific coast of South AmericaJournal of Biogeography, 45
R. Williams, C. Allen, J. Kelleway (2011)
Saltmarsh of the Parramatta River-Sydney Harbour : determination of cover and species composition including comparison of API and pedestrian survey
Michael Osland, N. Enwright, R. Day, T. Doyle (2013)
Winter climate change and coastal wetland foundation species: salt marshes vs. mangrove forests in the southeastern United StatesGlobal Change Biology, 19
R. Pressey, P. Adam (1995)
A review of wetland inventory and classification in AustraliaVegetatio, 118
C. Finlayson, N. Davidson, A. Spiers, N. Stevenson (1999)
Global wetland inventory – current status and future prioritiesMarine and Freshwater Research, 50
K. Gedan, B. Silliman, M. Bertness (2009)
Centuries of human-driven change in salt marsh ecosystems.Annual review of marine science, 1
K. Poiani, B. Richter, Mark Anderson, H. Richter (2000)
Biodiversity Conservation at Multiple Scales: Functional Sites, Landscapes, and Networks, 50
Effective conservation of saltmarshes involves detailed and accurate mapping of their range, area of occupancy and plant community composition as part of region‐wide inventories. There is also a need to identify the major mesoscale influences on the distributions of types of saltmarsh, obligate saltmarsh plants and salt pans, and evaluate possible responses to macroclimatic changes. Tidal saltmarshes of Tasmania and its offshore islands (coastline of 4,882 km, spanning latitudes 39°40′ to 43°40′S), off south‐eastern Australia, were mapped at a high spatial resolution of 1 : 500–1 : 3,000. The distributions of types of saltmarsh, obligate plant taxa and salt pans were related to climatic, geomorphic and land‐use variation. The future distribution of climatically controlled species and communities was determined for two climate change scenarios. There was 58.6 km2 of tidal saltmarsh in Tasmania in 61 mesoscale complexes. The complexes were classified into three broad saltmarsh groups, which together offer a more ecologically relevant planning unit for saltmarsh conservation than macroscale bioregions. The small median patch size of 0.2 ha demonstrates the effectiveness of the manual interpretation and mapping with extensive field checking. Mapping of these smaller saltmarshes provides them recognition within the land use planning and approvals process. Climatic, but not geomorphic and land‐use, factors have strong effects on the distribution of saltmarsh plant communities, species and salt pans in Tasmania. Mean annual rainfall was most significant in predicting saltmarsh extent, range, plant community composition, salt pans and the three saltmarsh groups. Mean annual daily minimum temperature and saltmarsh area best predicted obligate plant distributions. Projected wetter and drier climatic change by 2100 is not expected to substantially alter macroscale plant community patterns but may reduce the range of the rare herb Wilsonia humilis R.Br. However, stochastic disturbances may continue to play an important role at local scales.
Aquatic Conservation: Marine and Freshwater Ecosystems – Wiley
Published: May 1, 2019
Keywords: ; ; ; ; ; ; ; ; ;
Read and print from thousands of top scholarly journals.
Already have an account? Log in
Bookmark this article. You can see your Bookmarks on your DeepDyve Library.
To save an article, log in first, or sign up for a DeepDyve account if you don’t already have one.
Copy and paste the desired citation format or use the link below to download a file formatted for EndNote
Access the full text.
Sign up today, get DeepDyve free for 14 days.
All DeepDyve websites use cookies to improve your online experience. They were placed on your computer when you launched this website. You can change your cookie settings through your browser.