2015
DOI: 10.1890/es14-00534.1
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A global perspective on wetland salinization: ecological consequences of a growing threat to freshwater wetlands

Abstract: Abstract. Salinization, a widespread threat to the structure and ecological functioning of inland and coastal wetlands, is currently occurring at an unprecedented rate and geographic scale. The causes of salinization are diverse and include alterations to freshwater flows, land-clearance, irrigation, disposal of wastewater effluent, sea level rise, storm surges, and applications of de-icing salts. Climate change and anthropogenic modifications to the hydrologic cycle are expected to further increase the extent… Show more

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Cited by 705 publications
(532 citation statements)
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References 340 publications
(407 reference statements)
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“…If surface waters become more saline due to sealevel rise or freshwater limitations, coastal wetlands may transition to a more salt-tolerant plant communities and accumulate less total carbon in their soils (Williams and Rosenheim 2015;Herbert et al 2015). Conversely, if more freshwater reaches the coast via riverine discharge, restoration management actions such as large river diversions, or increased precipitation events, coastal wetlands may become fresher and accumulate more soil carbon in the short term (Morris et al 2013).…”
Section: Coastwide Tc Short-term Accumulationmentioning
confidence: 99%
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“…If surface waters become more saline due to sealevel rise or freshwater limitations, coastal wetlands may transition to a more salt-tolerant plant communities and accumulate less total carbon in their soils (Williams and Rosenheim 2015;Herbert et al 2015). Conversely, if more freshwater reaches the coast via riverine discharge, restoration management actions such as large river diversions, or increased precipitation events, coastal wetlands may become fresher and accumulate more soil carbon in the short term (Morris et al 2013).…”
Section: Coastwide Tc Short-term Accumulationmentioning
confidence: 99%
“…For example, it is predicted that as air and sea temperatures increase, some herbaceous wetland vegetation will be replaced with tropical woody mangrove species (Comeaux et al 2012;Osland et al 2012;Doughty et al 2015) and that these community shifts may influence carbon production and accumulation rates in wetland soils. Sea-level rise is also predicted to produce more saline environmental conditions that could drive transitions of fresh marshes to more saline marsh types (Herbert et al 2015) or drive salt marsh transgression inland (Kirwan et al 2016). In addition, large-scale restoration projects could introduce more fresh water to some estuaries, resulting in fresher marsh types (Morris et al 2013).…”
Section: Introductionmentioning
confidence: 99%
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“…Because salinity and sulfate availability are often correlated, it can be difficult to disentangle these two factors; Chambers et al (2011) isolated their effects in a laboratory manipulation and found that seawater (sulfate) had a more dramatic and longer lasting effect on CH 4 production than saltwater (NaCl). Nevertheless, salinity often places additional stress on organisms, such that saltwater intrusion alters microbial and plant communities (Herbert et al, 2015). Additionally, saltwater intrusion can influence cation exchange in the sediments, such that calcium is mobilized, which can coprecipitate with phosphate, and ammonium is released, all of which can shift a wetland towards P rather than N limitation (Herbert et al, 2015;van Dijk et al, 2015).…”
Section: Non-tidal Freshwater and Tidal Brackish Wetland Comparisonmentioning
confidence: 99%
“…Nevertheless, salinity often places additional stress on organisms, such that saltwater intrusion alters microbial and plant communities (Herbert et al, 2015). Additionally, saltwater intrusion can influence cation exchange in the sediments, such that calcium is mobilized, which can coprecipitate with phosphate, and ammonium is released, all of which can shift a wetland towards P rather than N limitation (Herbert et al, 2015;van Dijk et al, 2015). Although we did not directly measure these effects of salinity and therefore cannot rule them out, we hypothesize that sulfate availability and differences in functional microbial guilds are primarily responsible for differences in CH 4 production rather than salinity and salinity-induced cation exchange.…”
Section: Non-tidal Freshwater and Tidal Brackish Wetland Comparisonmentioning
confidence: 99%