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1.
In Louisiana, salt marshes are being created in an effort to offset the large loss of such habitat that has occurred over the last 50 yr. Primary productivity is an important function and indicator of success for salt marsh creation and restoration projects. The aim of this study was to determine whether the aboveground and belowground productivity of the dominant salt marsh grassSpartina alterniflora in created marshes in southwest Louisiana began to approximate productivity levels in natural marshes, over time. Net annual aboveground primary productivity (NAPP) was measured by a harvest technique, while the ingrowth core method was used to estimate net annual belowground primary productivity (NBPP). NAPP levels were similar to those found in other, Louisiana salt marshes, while NBPP levels were similar to or higher than the reported range forS. alterniflora studied along the Atlantic and Gulf of Mexico coasts. NAPP tended to decrease as the created marshes aged, but the levels in the oldest, 19 year old, created marsh were still well above values measured in the, natural marshes. It was estimated that it would take 35 yr after marsh creation for NAPP in the created marshes to become equivalent to that in natural marshes. NBPP in the created marshes became equivalent to levels found in the natural marshes after 6–8 yr, but then belowground production increased with marsh age, reaching an asymptote that surpassed natural marsh levels. Equivalency in primary productivity has not been reached in these marshes. Elevation also affected productivity, as higher elevational sites with greater topographic heterogeneity had significantly lower aboveground and belowground biomass levels than those with elevations closer to mean sea level. This underscores the need to construct marshes so that their mean elevation and degree of topographic heterogeneity are similar to natural marshes. 相似文献
2.
In deltaic marshes, mineral sediment promotes positive elevation change and counters subsidence and sea level rise. In many
such marshes sediment deficits result in wetland loss. One new way to address sediment deficiency is to supply marshes with
sediments in a slurry that deposits the sediment in a thin layer over a large area. The long-term effects of this strategy
are poorly understood. In a rapidly submerging,Spartina alterniflora salt marsh, we tested how different amounts of sediment ameliorated the effects of sea level rise and subsidence over 7 yr
(1992–1998). Sediment slurry enrichment likely affected plants and soils by two mechanisms. It increased elevation and soil
bulk density, leading to increased plant vigor and soil condition. These effects were long lasting, such that by 1998 areas
receiving moderate amounts of sediment (5–12 cm relative elevation) had better plant vigor and soil condition compared to
areas not receiving sediment (55% cover versus 20%; bulk densities of 0.4–1.0 g cm−3 versus 0.2 g cm−3; 0 mM hydrogen sulfide versus > 1.0 mM). The sediment slurry also had high nutrient content, which resulted in a pulse of
growth, especially in areas receiving the most sediment (areas > 12 cm relative elevation initially had >90% cover and canopy
heights >1.6 m). This nutrient-induced growth spurt was short lived and faded after 3 yr, at which point the long lasting
effects of increased elevation probably became the dominant factor promoting plant vigor and soil condition. Moderate levels
of sediment generated the most beneficial and long lasting effects to the vegetation and soils. This degree of sediment slurry
addition countered the effects of subsidence and sea level rise, but not so much as to surpass the intertidal position to
whichS. alterniflora is best adapted. 相似文献
3.
Bibit Halliday Traut 《Estuaries and Coasts》2005,28(2):286-295
In the salt marshes of Tomales Bay, California, where grazing by cattle increases the input of nitrogen to the marsh (either directly or indirectly as runoff from within the salt marsh watershed), high salt marsh vegetation is dominated byDistichlis spicata and is less diverse than marshes without excess nutrients. Using a field experiment, I investigated the role of soil fertility on the plant community of the high salt marsh. I hypothesized that when soil fertility is increased by nitrogen addition plant productivity will increase, as indicated by height, biomass, and cover, and competitive exclusion, byD. spicata, will lead to a reduction in species richness and evenness, especially where the initial density ofDistichlis is high (from transplanting). After two growing seasons, biweekly nitrogen addition to the high salt marsh led to increased plant biomass and cover. Diversity was not reduced, and space preemption byDistichlis-transplants did not confer a competitive advantage. Although the dominant species thrived (e.g.,Salicornia virginica, D. spicata, Triglochin concinna) they did not displace subdominant species and decrease diversity. The vegetation response in this high salt marsh system does not support the hypothesis that as biomass and cover (indicators of productivity) increase in response to increased nitrogen, competitive exclusion will occur and diversity will decrease. 相似文献
4.
Lotte Oosterlee Tom J. S. Cox Wouter Vandenbruwaene Tom Maris Stijn Temmerman Patrick Meire 《Estuaries and Coasts》2018,41(3):613-625
Tidal marsh (re)creation on formerly embanked land is increasingly executed along estuaries and coasts in Europe and the USA, either by restoring complete or by reduced tidal exchange. Ecosystem functioning and services are largely affected by the hydro-geomorphologic development of these areas. For natural marshes, the latter is known to be steered by feedbacks between tidal inundation and sediment accretion, allowing marshes to reach and maintain an equilibrium elevation relative to the mean sea level. However, for marsh restoration sites, these feedbacks may be disturbed depending on the restoration design. This was investigated by comparing the inundation-elevation change feedbacks in a natural versus restoration site with reduced tidal exchange in the Scheldt estuary (Belgium). This study analyzes long-term (9 years) datasets on elevation change and tidal inundation properties to disentangle the different mechanisms behind this elevation-inundation feedback. Moreover, subsequent changes in sediment properties that may affect this feedback were explored. In the restoration area with reduced tidal exchange, we found a different elevation-inundation feedback than on natural marshes, which is a positive feedback on initially high sites (i.e., sediment accretion leads to increasing inundation, hence causing accelerating sediment accretion rates) and a gradual silting up of the whole area. Furthermore, there is evidence for the presence of a relict consolidated sediment layer. Consequently, shallow subsidence is less likely to occur. Although short-term ecological development of the tidal marsh was not impeded, long-term habitat development may be affected by the differences in hydro-geomorphological interactions. An increase of inundation frequency on the initially high sites may cause inhibition of habitat succession or even reversed succession. Over time, the climax state of the restoration area may be different compared to natural marshes. Moreover, sediment-related ecosystem services, such as nutrient and carbon burial, may be positively influenced because of continuing sedimentation, although flood water storage potential will decrease with increasing elevation. Depending on the restoration goals, ecosystem trajectories and delivery of ecosystem services can be controlled by adaptive management of the tidal volume entering the restoration area. 相似文献
5.
Marsh sediment accumulation is predominately a combination of in situ organic accumulation and mineral sediment input during inundation. Within the Pamlico River Estuary (PRE), marsh inundation is dependent upon event (e.g., storms) and seasonal wind patterns due to minimal astronomical tides (<10 cm). A better understanding of the processes controlling sediment deposition and, ultimately, marsh accretion is needed to forecast marsh sustainability with changing land usage, climate, and sea level rise. This study examines marsh topography, inundation depth, duration of inundation, and wind velocity to identify relationships between short-term deposition (tile-based) and long-term accumulation (210Pb and 137Cs) recorded within and adjacent to the PRE. The results of this study indicate (1) similar sedimentation patterns between the interior marsh and shore-side marsh at different sites regardless of elevation, (2) increased sedimentation (one to two orders of magnitude, 0.04–4.54 g m?2 day?1) within the interior marsh when the water levels exceeded the adjacent topography (e.g., storm berm), and (3) that short-term sea level changes can have direct effects on sediment delivery to interior marshes in wind-driven estuarine systems. 相似文献
6.
Graham K. MacDonald Paula E. Noel Danika van Proosdij Gail L. Chmura 《Estuaries and Coasts》2010,33(1):151-160
We assess the status of channel networks and pools of two tidal salt marshes recovering from more than a century of agricultural
reclamation on the Bay of Fundy, Canada. A process of largely unmanaged restoration occurred at these sites since abandonment
of agricultural activities during the first half of the twentieth century. Each recovering marsh was compared to a reference
marsh that was never drained or ditched. We field mapped channel networks at all marshes and used aerial photographs to map
the pre-abandonment channel network at one of the sites. The recovering marshes have hybrid channel networks that feature
highly variable channel morphologies, loss of original channels, and incorporation of drainage ditches. Although channel networks
in recovering marshes integrate agricultural ditches, the recovering marsh networks may not be substantially increased in
length or density. Our aerial photograph analysis shows that channel density at one of the recovering marshes is comparable
to the pre-abandonment density, but with reduced sinuosity. Field mapping of permanent tidal pools on the lower Bay marshes
revealed that pools cover 13% of the recovering marsh, compared to ∼5% of the reference marsh. This study demonstrates that
these essential marsh features can be regained through restoration or simple abandonment of drainage infrastructure. 相似文献
7.
One year’s measurements of surficial sedimentation rates (1986–1987) for 26 Maine marsh sites were made over marker horizons of brick dust. Observed sediment accumulation rates, from 0 to 13 mm yr?1, were compared with marsh morphology, local relative sea-level rise rate, mean tidal range, and ice rafting activity. Marshes with four different morphologies (back-barrier, fluvial, bluff-toe, and transitional) showed distinctly different sediment accumulation rates. In general, back-barrier marshes had the highest accumulation rates and blufftoe marshes had the lowest rates, with intermediate values for transitional and fluvial marshes. No causal relationship between modern marsh sediment accumulation rate and relative sea-level rise rate (from tide gauge records) was observed. Marsh accretionary balance (sediment accumulation rate minus relative sea-level rise rate) did not correlate with mean tidal range for this meso- to macro-tidal area. Estimates of ice-rafted debris on marsh sites ranged from 0% to >100% of measured surficial sedimentation rates, indicating that ice transport of sediment may make a significant contribution to surficial sedimentation on Maine salt marshes. 相似文献
8.
Vertical accretion of impounded marsh and adjacent natural marsh at four sites in southwestern Louisiana was estimated in 1994 by determining the depth of a stratum containing137Cs deposited in 1963. With relative marsh elevation, soil bulk density, organic matter content, and organic and mineral matter accumulation rates were used to describe soil formation. Three sites were impounded in 1956 and one site in 1951. Impounded marshes had lower marsh surface elevation than natural marshes because of hydrologic isolation from tidal sediment subsidies and substrate oxidation during forced drying. The elevation of natural marshes ranged from 12 cm to 42 cm higher than the elevation of the impounded marshes in 1963 and from 20 cm to 32 cm higher in 1994. Vertical accretion between 1963 and 1994 ranged from 9 cm to 28 cm in impounded marsh and from 15 cm to 21.5 cm in natural marsh. Only in impounded marsh that remained permanently flooded was accretion greater than in natural marsh. 相似文献
9.
A coastwide study of the relationship between marsh aggradation and water level changes along the rapidly deteriorating Louisiana gulf coast was conducted. Rate of vertical marsh accretion determined from137Cs dating was compared to water level changes or submergence. Results identified marsh locations that are not keeping pace with submergence. Coastwide vertical accretion rates on the order of 0.7–0.8 cm/yr are not sufficient to keep pace with water level increases occurring at rates in most locations of over 1.0 cm/yr. Submergence rates were four to five times greater than eustatic sea level change for the Gulf of Mexico. Louisiana gulf coast marshes are likely to continue deteriorating unless means are implemented for distributing Mississippi River sediment to the marsh. It is estimated that sediment equivalent to less than 10 percent of the present annual suspended load of the Mississippi would provide enough sediment for marsh accretionary processes to compensate for submergence or water level increase. 相似文献
10.
Currently, the largest tidal wetlands restoration project on the US Pacific Coast is being planned and implemented in southern San Francisco Bay; however, knowledge of baseline conditions of salt marsh extent in the region prior to European settlement is limited. Here, analysis of 24 sediment cores collected from ten intact southern San Francisco Bay tidal marshes were used to reconstruct spatio-temporal patterns of marsh expansion to provide historic context for current restoration efforts. A process-based marsh elevation simulation model was used to identify interactions between sediment supply, sea-level rise, and marsh formation rates. A distinct age gradient was found: expansion of marshes in the central portion of southern San Francisco Bay dated to 500 to 1500 calendar years before present, while expansion of marshes in southernmost San Francisco Bay dated to 200 to 700 calendar years before present. Thus, much of the tidal marsh area mapped by US Coast Survey during the 1853–1857 period were in fact not primeval tidal marshes that had persisted for millennia but were recently formed landscapes. Marsh expansion increased during the Little Ice Age, when freshwater inflow and sediment influx were higher than during the previous millennium, and also during settlement, when land use changes, such as introduction of livestock, increased watershed erosion, and sediment delivery. 相似文献
11.
Charles T. Roman 《Estuaries and Coasts》2017,40(3):711-716
Many salt marshes throughout southern New England are exhibiting a trend toward submergence, as reported in this volume and other published literature. This paper provides a brief perspective on sea-level rise and the many other interacting factors that contribute to marsh submergence in this and other regions. Curtailing nutrient loading and removing or altering barriers (e.g., dams, dikes) to the delivery of suspended sediment to marshes are discussed as management or restoration techniques to consider for increasing long-term sustainability of marshes. Adaptation measures are many (e.g., thin-layer sediment application to marsh surface, facilitation of landward marsh migration, shoreline stabilization), but all require study to evaluate their potential for enhancing resilience. Research, monitoring, and dynamic modeling, coupled with appropriate management and adaptation approaches implemented at local and regional scales, will contribute to the challenge of sustaining salt marshes in an uncertain future of sea-level rise, other climate factors, and stressors associated with a developing coastal zone. 相似文献
12.
We compared the functions and values of fringing salt marshes to those of meadow marshes along the southern Maine/New Hampshire
coast. Differences included soil organic matter content, plant species richness, and percent cover of high and low-marsh species.
More sediment was trapped per unit area in fringing marshes than in meadow marshes, but this difference was not significant.
Similarities included aboveground and belowground peak season biomass and the ability to dampen wave energy. Both marsh types
reduced the height of waves coming onto the marsh surface by 63% only 7 m into the marsh. Fringing marshes are diverse in
terms of their physical characteristics (width, length, slope, elevation, soils). Despite their small size, they are valuable
components of estuaries, performing many ecological functions to the same degree as nearby meadow marshes. More effort should
be made to include them in regional efforts to conserve and restore coastal habitats. 相似文献
13.
Ilia Rochlin Mary-Jane James-Pirri Susan C. Adamowicz Mary E. Dempsey Thomas Iwanejko Dominick V. Ninivaggi 《Estuaries and Coasts》2012,35(3):727-742
An integrated marsh management (IMM) project in an urbanized watershed on Long Island, New York, USA, aimed to mitigate salt marsh degradation and to reduce mosquito production by an innovative combination of restoration and open marsh water management methods. The grid ditch network at two treatment marshes was replaced with naturalized tidal channels and ponds. Effects of the hydrologic alterations were monitored utilizing a before–after–control–impact approach. The treatment marshes experienced a number of beneficial outcomes including a fourfold reduction in the invasive Phragmites australis and increased native vegetation cover in the most degraded portions of the marsh, increased abundance and diversity of marsh killifish and estuarine nekton species, higher shorebird and waterfowl densities, and increased avian species diversity. The successful implementation of IMM concept led to improved marsh health and diminished mosquito production. Therefore, this study may serve as a template for similar large-scale integrated salt marsh restoration projects. 相似文献
14.
Hummock-hollow microtopography is characteristic of many freshwater wetland systems. It is comprised of elevated, vegetated
hummocks and lower elevation hollows; the latter are usually unvegetated, with reducing conditions in sediments unfavorable
for plant growth. This microtopography is also often found in interior regions of brackish marshes, where flood duration is
high and salinity fluctuations are prominent. Previous investigation showed this spatial patterning to be relatively stable
over time and suggested that these microenvironments are produced by the plants themselves. This study investigates the possible
mechanisms and controlling factors of this microtopography and considers the effect of different salinity regimes. We examined
microtopographic variability of vegetation and sediment biogeochemistry in two interior tidal marshes, a freshwater-oligohaline
marsh and a mesohaline marsh, both of which exhibited fine-scale spatial variability. Within a 2-yr period, the freshwater-oligohaline
site demonstrated a labile response of both vegetation and sediment chemistry to interannual variability in salinity and sulfide
concentrations, whereas the microscale spatial variability of the mesohaline system persisted. Geochronological assessment
of the mesohaline marsh, where microtopographic variability was relatively stable, supported the hypothesis that the formation
of the hummock-hollow topography is driven by the plants, rather than developing as a result of underlying physical variability.
We propose that brackish marsh vegetation alters the sedimentary environment in such a way as to maximize growth under high-stress,
variable conditions. The adaptive advantage of this strategy was illustrated in the accretion rates measured at the higher
salinity marsh, which were indistinguishable between the interior hummock sediments and those of an adjacent homogeneous bank
marsh. 相似文献
15.
R. Michael Erwin Donald R. Cahoon Diann J. Prosser Geoffrey M. Sanders Phillippe Hensel 《Estuaries and Coasts》2006,29(1):96-106
Mid Atlantic coastal salt marshes contain a matrix of vegetation diversified by tidal pools, pannes, and creeks, providing
habitats of varying importance to many species of breeding, migrating, and wintering waterbirds. We hypothesized that changes
in marsh elevation were not sufficient to keep pace with those of sea level in both vegetated and unvegetatedSpartina alterniflora sites at a number of mid lagoon marsh areas along the Atlantic Coast. We also predicted that northern areas would suffer
less of a deficit than would southern sites. Beginning in August 1998, we installed surface elevation tables at study sites
on Cape Cod, Massachusetts, southern New Jersey, and two locations along Virginia's eastern shore. We compared these elevation
changes over the 4–4.5 yr record with the long-term (>50 yr) tidal records for each locale. We also collected data on waterbird
use of these sites during all seasons of the year, based on ground surveys and replicated surveys from observation platforms.
Three patterns of marsh elevation change were found. At Nauset Marsh, Cape Cod, theSpartina marsh surface tracked the pond surface, both keeping pace with regional sea-level rise rates. In New Jersey, the ponds are
becoming deeper while marsh surface elevation remains unchanged from the initial reading. This may result in a submergence
of the marsh in the future, assuming sea-level rise continues at current rates. Ponds at both Virginia sites are filling in,
while marsh surface elevation rates do not seem to be keeping pace with local sea-level rise. An additional finding at all
sites was that subsidence in the vegetated marsh surfaces was less than in unvegetated areas, reflecting the importance of
the root mat in stabilizing sediments. The implications to migratory waterbirds are significant. Submergence of much of the
lagoonal marsh area in Virginia and New Jersey over the next century could have major negative (i.e., flooding) effects on
nesting populations of marsh-dependent seaside sparrowsAmmodramus maritimus, saltmarsh sharp-tailed sparrowsAmmodramus caudacutus, black railsLaterallus jamaicensis, clapper railsRallus longirostris. Forster's ternsSterna forsteri, common ternsSterna hirundo, and gull-billed ternsSterna nilotica. Although short-term inundation of many lagoonal marshes may benefit some open-water feeding ducks, geese, and swans during
winter, the long-term ecosystem effects may be detrimental, as wildlife resources will be lost or displaced. With the reduction
in area of emergent marsh, estuarine secondary productivity and biotic diversity will also be reduced. 相似文献
16.
Ecosystem Responses of a Tidal Freshwater Marsh Experiencing Saltwater Intrusion and Altered Hydrology 总被引:5,自引:0,他引:5
Scott C. Neubauer 《Estuaries and Coasts》2013,36(3):491-507
Tidal freshwater marshes exist in a dynamic environment where plant productivity, subsurface biogeochemical processes, and soil elevation respond to hydrological fluctuations over tidal to multi-decadal time scales. The objective of this study was to determine ecosystem responses to elevated salinity and increased water inputs, which are likely as sea level rise accelerates and saltwater intrudes into freshwater habitats. Since June 2008, in situ manipulations in a Zizaniopsis miliacea (giant cutgrass)-dominated tidal freshwater marsh in South Carolina have raised porewater salinities from freshwater to oligohaline levels and/or subtly increased the amount of water flowing through the system. Ecosystem-level fluxes of CO2 and CH4 have been measured to quantify rates of production and respiration. During the first 20 months of the experiment, the major impact of elevated salinity was a depression of plant productivity, whereas increasing freshwater inputs had a greater effect on rates of ecosystem CO2 emissions, primarily due to changes in soil processes. Net ecosystem production, the balance between gross ecosystem production and ecosystem respiration, decreased by 55% due to elevated salinity, increased by 75% when freshwater inputs were increased, and did not change when salinity and hydrology were both manipulated. These changes in net ecosystem production may impact the ability of marshes to keep up with rising sea levels since the accumulation of organic matter is critical in allowing tidal freshwater marshes to build soil volume. Thus, it is necessary to have regional-scale predictions of saltwater intrusion and water level changes relative to the marsh surface in order to accurately forecast the long-term sustainability of tidal freshwater marshes to future environmental change. 相似文献
17.
Ditching and Ditch-Plugging in New England Salt Marshes: Effects on Hydrology, Elevation, and Soil Characteristics 总被引:1,自引:0,他引:1
Anthropogenic activities in New England salt marshes have altered hydrologic flows in various ways, but unintended consequences from some types of habitat modifications have received little attention. Specifically, ditches have existed on salt marshes for decades, but the effects of these hydrologic alterations are only poorly understood. Ditch-plugging is a more recent methodology used for salt marsh habitat enhancement and mosquito control, but the long-term effects from this management practice are also unclear. The interactions involving marsh surface elevation, soil characteristics, and hydrologic regimes result in feedbacks that regulate the salt marsh self-maintenance process, and these interactions vary with hydrologic modification. Using natural tidal creeks and pools as controls, we examined the effects of ditching and plugging, respectively, on hydrology, surface elevations, and soils. Results showed the most apparent effects of altered hydrology from ditching are prolonged pore-water retention in the rooting zone and significantly lower soil bulk density and mineral content when compared with natural creek habitat. From a management perspective, the important question is whether the combined alterations to physical and biological processes will hinder the marsh’s ability to keep pace with increasing rates of sea level rise, especially in more heavily ditched marshes. In contrast, ditch-plugging results in the decoupling of feedback processes that promote salt marsh self-maintenance and in doing so, threatens marsh stability and resilience to climate change. High surface water levels, permanently saturated soils, marsh subsidence, and significantly lower bulk density, carbon storage, soil strength, and redox levels associated with hydrologic alterations from ditch-plugging all support this conclusion. 相似文献
18.
Few studies concerning tide-restricted and restoring salt marshes emphasize fishes and decapod crustaceans (nekton) despite
their ecological significance. This study quantifies nekton utilization of three New England salt marshes under tide-restricted
and restoring conditions (Hatches Harbor, Massachusetts; Sachuest Point and Galilee, Rhode Island). The degree of tidal restriction
differed among marshes allowing for an examination of nekton utilization patterns along a gradient of tidal restriction and
subsequent restoration. Based on sampling in shallow subtidal creeks and pools, nekton density and richness were significantly
lower in the restricted marsh compared to the unrestricted marsh only at the most tide-restricted site (Sachuest Point). The
dissimilarity in community composition between the unrestricted and restricted marsh sites increased with more pronounced
tidal restriction. The increase in nekton density resulting from tidal restoration was positively related to the increase
in tidal range. Species richness only increased with restoration at the most tide-restricted site; no significant change was
observed at the other two sites. These patterns suggest that only severe tidal restrictions significantly reduce the habitat
value of New England salt marshes for shallow subtidal nekton. This study suggests that the greatest responses by nekton,
and the most dramatic shift towards a more natural nekton assemblage, will occur with restoration of severely restricted salt
marshes. 相似文献
19.
Through their physiological effects on ion, oxygen, and carbon balance, respectively, salinity, sulfide, and prolonged flooding
combine to constrain the invasion and spread ofPhragmites in tidal wetlands. Initial sites of vigorous invasion by seed germination and growth from rhizome fragments appear limited
to sections of marsh where salinity is <10‰, sulfide concentrations are less than 0.1 mM, and flooding frequency is less than
10%. In polyhaline tidal wetlands the invasion sites include the upland fringe and some high marsh creek banks. The zones
of potential invasion tend to be larger in marshes occupying lower-salinity portions of estuaries and in marshes that have
been altered hydrologically. Owing to clonal integration and a positive feedback loop of growth-induced modification of edaphic
soil conditions, however, a greater total area of wetland is susceptible toPhragmites expansion away from sites of establishment. Mature clones have been reported growing in different marshes with salinity up
to 45‰, sulfide concentration up to 1.75 mM, and flooding frequency up to 100%. ForPhragmites establishment and expansion in tidal marshes, windows of opportunity open with microtopographic enhancement of subsurface
drainage patterns, marsh-wide depression of flooding and salinity regimes, and variation in sea level driven by global warming
and lunar nodal cycles. To avoidPhragmites monocultures, tidal wetland creation, restoration, and management must be considered within the context of these different
scales of plant-environment interaction. 相似文献
20.
Andrew S. Wozniak Charles T. Roman Sam C. Wainright Richard A. McKinney Mary-Jane James-Pirri 《Estuaries and Coasts》2006,29(4):568-578
Primary producer (angiosperms, macroalgae, submerged aquatic vegetation), suspended particulate matter, andFundulus heteroclitus isotope values (δ13C, δ15N, δ34S) were examined to assess their use as indicators for changes in food web support functions in tidally-restored salt marshes.
Study sites, located throughout the southern New England region (USA), ranged fromSpartina alterniflora-dominated reference marshes, marshes under various regimes and histories of tide restoration, and a severely tide-restrictedPhragmites australis marsh.Fundulus δ13C values were greater for fish from referenceSpartina marshes than for fish from adjacent tide-restricted or tide-restored marshes where higher percent cover of C3 plants, lower water column salinities, and more negative dissolved inorganic δ13C values were observed. The difference inFundulus δ13C values between a tide-restrictedPhragmites marsh and an adjacent referenceSpartina marsh was great compared to the difference between marshes at various stages of tide restoration and their respective reference
marshes, suggesting that food web support functions are restored as the degree of tidal restriction is lessened. While a multiple
isotopic approach can provide valuable information for determining specific food sources to consumers, this study demonstrates
that monitoringFundulus δ13C values alone may be useful to evaluate the trajectory of ecological change for marshes undergoing tidal restoration. 相似文献