Centuries of Human-Driven Change in Salt Marsh Ecosystems

Gedan, Keryn B.; Silliman, Brian R.; Bertness, Mark D.

doi:10.1146/annurev.marine.010908.163930

Cited by 779 publications

(468 citation statements)

References 129 publications

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“…Much attention has been devoted to the understanding and description of the processes which lead to observed equilibria in the vertical direction, or lack thereof, producing a rather comprehensive understanding of the controlling biological and physical processes [Allen, 1990;Morris et al, 2002;D'Alpaos et al, 2007;Kirwan and Murray, 2007;Marani et al, 2007;Mudd et al, 2009;Marani et al, 2010]. On the contrary, "lateral" evolution mechanisms have received comparatively much less attention, even though marsh degradation associated with edge erosion is arguably the chief mechanism by which marshes in coastal areas worldwide are being lost [Schwimmer, 2001;Gedan et al, 2009;van de Koppel et al, 2005;Mariotti and Fagherazzi, 2010]. Briefly, the current process understanding relates the erosion of a cliffed marsh edge (see Figure 1) to the fluctuating forces exerted on the margin by wave impact, which produces the removal of the bank material.…”

Section: Introductionmentioning

confidence: 99%

Understanding and predicting wave erosion of marsh edges

Marani

D’Alpaos

Lanzoni

et al. 2011

Geophys. Res. Lett.

207

234

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[1] Margin lateral erosion is arguably the main mechanism leading to marsh loss in estuaries and lagoons worldwide. Our understanding of the mechanisms controlling marsh edge erosion is currently quite limited and current predictive models rely on empirical laws with limited general applicability. We propose here a simple theoretical treatment of the problem based on dimensional analysis. The identification of the variables controlling the problem and the application of Buckingham's theorem show, purely on dimensional grounds, that the rate of edge erosion and the incident wave power density are linearly related. The predictive ability of the derived relationship is then evaluated, positively, using new long-term observations from the Venice lagoon (Italy) and by re-interpreting data available in previous literature.

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Section: Introductionmentioning

confidence: 99%

Understanding and predicting wave erosion of marsh edges

Marani

D’Alpaos

Lanzoni

et al. 2011

Geophys. Res. Lett.

207

234

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“…However, many other human pressures-most particularly nutrification, habitat conversion, and the overexploitation and introduction of species-also intensified with the expansion of human populations and technology during the Industrial Revolution and the post-World War II "Great Acceleration" (2,4,17,18) and are equally relevant to conservation and restoration efforts, as well as to basic ecological research. These pressures, moreover, started much earlier during preceding centuries to millennia at regional scales, both on land and in coastal seas, and have been accompanied by biological-stress syndromes (19), such as decreased body size, population size, trophic levels, and diversity, as well as functional and complete extinction of species (14,(20)(21)(22)(23)(24). These nonclimate factors are now as global as climate change (Fig.…”

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confidence: 99%

Biology in the Anthropocene: Challenges and insights from young fossil records

Kidwell

2015

Proc. Natl. Acad. Sci. U.S.A.

124

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With overwhelming evidence of change in habitats, biologists today must assume that few, if any, study areas are natural and that biological variability is superimposed on trends rather than stationary means. Paleobiological data from the youngest sedimentary record, including death assemblages actively accumulating on modern land surfaces and seabeds, provide unique information on the status of present-day species, communities, and biomes over the last few decades to millennia and on their responses to natural and anthropogenic environmental change. Key advances have established the accuracy and resolving power of paleobiological information derived from naturally preserved remains and of proxy evidence for environmental conditions and sample age so that fossil data can both implicate and exonerate human stressors as the drivers of biotic change and permit the effects of multiple stressors to be disentangled. Legacy effects from Industrial and even pre-Industrial anthropogenic extirpations, introductions, (de)nutrification, and habitat conversion commonly emerge as the primary factors underlying the present-day status of populations and communities; within the last 2 million years, climate change has rarely been sufficient to drive major extinction pulses absent other human pressures, which are now manifold. Young fossil records also provide rigorous access to the baseline composition and dynamics of modern-day biota under pre-Industrial conditions, where insights include the millennial-scale persistence of community structures, the dominant role of physical environmental conditions rather than biotic interactions in determining community composition and disassembly, and the existence of naturally alternating states.biodiversity | ecology | conservation | paleobiology | paleoecology

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“…Recent research from the USA highlights the role of molluscs in saltmarsh die-off by selectively consuming saltmarsh vegetation (Gedan et al 2009); however, the role of herbivorous molluscs as habitat modifiers and top-down consumers has not been observed in Australia, but requires further attention. Mollusc adults and larvae are also prey for a range of estuarine predators, including eels, crabs, fish, waterbirds and mammals (Hollingsworth and Connolly 2006;Mazumder et al 2006;Roach 1998); these molluscs and other invertebrates appear to make an important contribution to the diet of fish feeding in saltmarsh (Mazumder et al 2006).…”

Section: Carbon and Aquatic Foodwebsmentioning

confidence: 99%

The significance and vulnerability of Australian saltmarshes: implications for management in a changing climate

Saintilan¹,

Rogers

2013

Mar. Freshwater Res.

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We review the distribution, status and ecology of Australian saltmarshes and the mechanisms whereby enhanced atmospheric carbon dioxide and associated climate change have influenced and will influence the provision of ecosystem goods and services. Research in temperate and subtropical saltmarsh has demonstrated important trophic contributions to estuarine fisheries, mediated by the synchronised massspawning of crabs, which feed predominantly on the C-4 saltmarsh grass Sporobolus virginicus and microphytobenthos. Saltmarshes also provide unique feeding and habitat opportunities for several species of threatened microbats and birds, including migratory shorebirds. Saltmarshes increased in extent relative to mangrove in Australia in both tide-and wave-dominated geomorphic settings through the latter Holocene, although historic trends have seen a reversal of this trend. Australian saltmarshes have some capacity to maintain elevation with respect to rising sea level, although in south-eastern Australia, the encroachment of mangrove and, in Tasmania, conversion of shrubland to herbfield in the past half-century are consistent with changes in relative sea level. Modelling of the impacts of projected sea-level rise, incorporating sedimentation and other surface-elevation drivers, suggests that the survival of saltmarsh in developed estuaries will depend on the flexible management of hard structures and other impediments to wetland retreat.

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Centuries of Human-Driven Change in Salt Marsh Ecosystems

Cited by 779 publications

References 129 publications

Understanding and predicting wave erosion of marsh edges

Understanding and predicting wave erosion of marsh edges

Biology in the Anthropocene: Challenges and insights from young fossil records

The significance and vulnerability of Australian saltmarshes: implications for management in a changing climate

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