Processes that influence carbon isotope variations in salt marsh sediments

Ember, LM; Williams, D. F.; Morris, JT

doi:10.3354/meps036033

Cited by 93 publications

(69 citation statements)

References 45 publications

(36 reference statements)

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“…These values are more positive in general compared to those reported by Lacerda et al (1986b) for the Sepetiba bay in Río do Janeiro, and may indicate the influence of carbon from marine organisms (Bouillon et al, 2003). We expected differences in carbon isotopic signatures to appear in those mangroves where S. densiflora made up a significant fraction of the vegetation cover due to its C4-photosynthesis (Ember et al, 1987), but it was not the case.…”

Section: Soilscontrasting

confidence: 47%

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Heterogeneity of elemental composition and natural abundance of stables isotopes of C and N in soils and leaves of mangroves at their southernmost West Atlantic range

et al. 2016

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Mangrove communities were selected in the state of Santa Catarina, Brazil, near their southernmost limit of distribution, to study mineral nutrient relation in soils and plants. Communities included three true mangrove species, Rhizophora mangle, Laguncularia racemosa and Avicennia germinans, and two associated species, the fern Acrostichum danaeifolium, and the grass Spartina densiflora. The sites included communities in the lower Río Tavares near Florianopolis city, Sonho beach near Palhoça city, and the Santo Antonio lagoon. These sites included a full range of mangroves under humid climate where winter temperatures, instead of salinity, may be the main factor regulating their productive capacity and species composition. Soil salinity was determined by the concentration of soluble Na, and soil C and N were linearly correlated indicating their association in organic matter. Tavares site showed higher specific conductivity, and concentrations of Na and Mg in the soil layer below 40 cm depth, indicating larger influence of marine water. Isotopic signature of C increased with soil depth suggesting that microorganisms decomposing organic matter are releasing 13 C depleted CO 2 . Nitrogen isotopic signature decreased with soil depth, indicating enrichment in 15 N possibly as a result of denitrification in the upper soil layers. Mineral elements in leaf tissues showed A. schaueriana with higher concentrations of N, P, Na, K, Cu, Zn, and Na/Ca ratio. Spartina densiflora was characterized by the lowest N and K concentrations, and the highest concentrations of Al and Fe. Rhizophora mangle and L. racemosa had the highest Ca concentrations. Carbon isotopic signatures identified S. densiflora as a C4 plant, and A. schaueriana as the mangrove species occupying comparatively more water stressed microsites than the rest. Leaf nitrogen isotopic signatures were positive, in correspondence with the soil values. The results support the hypothesis that sites sampled were comparatively fertile, because sediment transport through fresh water run-off is predominant in humid coasts, and therefore plants were not limited by nutrient supply, nor particularly stressed by soil salinity.Keywords: mangroves, soils, leaves, nutrients, stable isotopes, southwestern Atlantic latitudinal limit.Heterogeneidade da composição elementar e abundância natural de isótopos estáveis de C e N no solo e folhas dos manguezais no extremo sul da sua distribuição na costa Atlântica ocidental

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Section: Soilscontrasting

confidence: 47%

“…Concentration of C in soils varied from about 3 to a little above 8%, within the range expected for wetlands (Ember et al, 1987). The δ 13 C ranged from about -22 to -24.6 ‰, with a tendency for more positive values in the lower soil layer.…”

Section: Soilsmentioning

confidence: 92%

Heterogeneity of elemental composition and natural abundance of stables isotopes of C and N in soils and leaves of mangroves at their southernmost West Atlantic range

et al. 2016

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“…The polysaccharide components of Spartina and other plants are degraded by microorganisms at rates several-fold higher than the lignin component, leading to the gradual enrichment of lignin-derived C in remaining tissues (Benner et al 19843, 1986b(Benner et al 19843, , 1987. The observation that the stable C isotope composition of Spartina shifted to more negative values during decomposition as the relative concentration of lignin increased led to the hypothesis that Spartina may contribute significantly more to pools of sedimentary and particulate organic matter in salt marshes and adjacent coastal waters than would be predicted based on the C isotopic compositions of undegraded tissues (Benner et al 1987;Ember et al 1987;Fogel et al 1989).…”

mentioning

confidence: 99%

“…Stable C isotope compositions of sedimentary organic matter in marshes dominated by Spartina are consistently depleted in 13C (613C of -16 to -20%0) relative to Spartina plant tissues (613C of -13%0) (Haines 1976;Ember et al 1987). The relatively large difference bctween the bulk isotopic composition of Spartina tissues and the isotopic signature of sedimentary organic matter is suggestive that other sources of organic matter with isotopic values similar to those of sedimentary organic matter, such as algae, are dominant contributors to the organic C in sediments or that alterations of isotopic compositions occur during decomposition of plant tissues or both.…”

mentioning

confidence: 99%

“…Salt marshes on the southeastern seaboard of the U.S. are accreting sediments at rates ranging from 1.4 to 11 .O mm yr-' (Sharma et al 1987), and the organic matter contents of salt-1358 marsh sediments typically range from 5-20% (Ember et al 1987;Sharma et al 1987). The accretion of organic matter in salt-marsh sediments ranges from 70 to 225 g m-2 yr-' (assumes organic matter is 40 wt% C; Howes et al 1985;Wiegert and Pomeroy 198 1) and may be an important fate for a significant fraction of belowground production.…”

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confidence: 99%

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Diagenesis of belowground biomass of Spartina alterniflora in salt‐marsh sediments

Benner¹,

Fogel

Sprague

1991

Limnology & Oceanography

218

103

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Belowground biomass of Spartina alterniflora lost 55% of its organic matter during 18 months of decomposition in salt-marsh sediments. Significant losses of lignin were observed under highly reducing conditions confirming previous reports of lignin degradation in the absence of molecular oxygen. The submolecular components of lignin varied in susceptibility to degradation and were ranked in the following descending order of resistance to decomposition: V-P> S-C. The preferential degradation of 1 he cinnamyl and syringyl components constrains the quantitative usefulness of these compounds for estimating the contributions ofherbaceous and angiosperm tissues to pools of dissolved and particulate organic matter. The relative concentration of lignin increased about 1.6-fold during decomposition owing to the more rapid loss of polysaccharides.Two phases in nitrogen dynamics were evident during the decomposition study. During the first 4 months of decomposition there was a net loss of N from Spartina tissues at a rate of about 10 gg N g-l tissue d-I. After this initial phase of net N loss, a phase of N immobilization was evident and was tightly coupled with rates of microbial degradation of the tissues. Net rates of N immobilization were -19 pg N g-' tissue d -I; by the end of the 18-month study more N had accumulated in the tissues than was initially present. Stable N isotope composilions of decaying Spartina were also very dynamic and reflected the sources of N that were immobilized during decomposition and the N transformations that occurred on the detrital particles.The stable C isotope composition of the polysaccharide components of Spartina was -6%~ heavier than that of the lignin component. The isotopic compositions of these components retained the 6o/oo difference throughout the 18-month study. The stable C isotope composition of the bulk tissues, however, decreased gradually during decomposition as the isotopically heavier polysaccharides were preferentially lost. Residual material was relatively enriched in the isotopically lighter, lignin-deriveci C.'

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Placing barrier‐island transgression in a blue‐carbon context

Theuerkauf

Rodriguez

2017

Earth's Future

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Backbarrier saltmarshes are considered carbon sinks; however, barrier island transgression and the associated processes of erosion and overwash are typically not included in coastal carbon budgets. Here, we present a carbon‐budget model for transgressive barrier islands that includes a dynamic carbon‐storage term, driven by backbarrier‐marsh width, and a carbon‐export term, driven by ocean and backbarrier shoreline erosion. To examine the impacts of storms, human disturbances and the backbarrier setting of a transgressive barrier island on carbon budgets and reservoirs, the model was applied to sites at Core Banks and Onslow Beach, NC, USA. Results show that shoreline erosion and burial of backbarrier marsh from washover deposition and dredge‐spoil disposal temporarily transitioned each site into a net exporter (source) of carbon. The magnitude of the carbon reservoir was linked to the backbarrier setting of an island. Carbon reservoirs of study sites separated from the mainland by only backbarrier marsh (no lagoon) decreased for over a decade because carbon storage could not keep pace with erosion. With progressive narrowing of the backbarrier marsh, these barriers will begin to function more persistently as carbon sources until the reservoir is depleted at the point where the barrier welds with the mainland. Undeveloped barrier islands with wide lagoons are carbon sources briefly during erosive periods; however, at century time scales are net carbon importers (sinks) because new marsh habitat can form during barrier rollover. Human development on backbarrier saltmarsh serves to reduce the carbon storage capacity and can hasten the transition of an island from a sink to a source.

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Processes that influence carbon isotope variations in salt marsh sediments

Cited by 93 publications

References 45 publications

Heterogeneity of elemental composition and natural abundance of stables isotopes of C and N in soils and leaves of mangroves at their southernmost West Atlantic range

Heterogeneity of elemental composition and natural abundance of stables isotopes of C and N in soils and leaves of mangroves at their southernmost West Atlantic range

Diagenesis of belowground biomass of Spartina alterniflora in salt‐marsh sediments

Placing barrier‐island transgression in a blue‐carbon context

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