Bioturbator‐stimulated loss of seagrass sediment carbon stocks

Thomson, Alexandra C. G.; Trevathan-Tackett, Stacey M.; Maher, Damien T.; Ralph, Peter J.; Macreadie, Peter I.

doi:10.1002/lno.11044

Cited by 29 publications

(26 citation statements)

References 76 publications

(136 reference statements)

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“…The presence and density of fauna, especially large bioturbators, can be used as an indicator and predictor of the functional status of benthic environments (Eyre, 2011). Faunal impacts on C storage have been documented in many blue carbon habitats, including seagrass (Papaspyrou et al, 2004;Thomson, 2018). Herbivory can have direct impacts on cover and production through consumption, for example green turtles (Heithaus et al, 2014) and urchins (Rose et al, 1999) can remove most aboveground biomass.…”

Section: Discussionmentioning

confidence: 99%

“…In these anoxic conditions, bioturbation by callianassid shrimp can provide a substantial input of oxygen into the sediment, particularly through processes of bio-irrigation, which is predominantly used in biogeochemical processes and microbial respiration (Webb and Eyre, 2004). The remineralization processes promoted by callianassid burrowing activity can result in a 2 to 5 times increase in CO 2 emission (Thomson, 2018). Whilst callianassid shrimp are the most obvious bioturbators, seagrass removal resulted in a general shift in community structure toward larger bodied, more active taxa; perhaps as the physical barriers of dense seagrass canopy and rhizomes were removed, facilitating predation, or as the sediment chemistry changed, permitting higher sedimentary oxygen levels.…”

Section: Discussionmentioning

confidence: 99%

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Seagrass Removal Leads to Rapid Changes in Fauna and Loss of Carbon

et al. 2019

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Seagrass habitats are important natural carbon sinks, with an average of ∼14 kg C m −2 buried in their sediments. The fate of this carbon following seagrass removal or damage has major environmental implications but is poorly understood. Using a removal experiment lasting 18 months at Gazi Bay, Kenya, we investigated the impacts of seagrass loss on sediment topography, hydrodynamics, faunal community structure and carbon dynamics. Sediment pins were used to monitor surface elevation. The effects of seagrass removal on water velocity was investigated using Plaster of Paris dissolution. Sediment carbon concentration was measured at the surface and down to 50 cm. Rates of litter decay at three depths in harvested and control treatments were measured using litter bags. Drop samples, cores, and visual counts of faunal mounds and burrows were used to monitor the impact of seagrass removal on the epifaunal and infaunal communities. Whilst control plots showed sediment elevation, harvested plots were eroded (7.6 ± 0.4 and −15.8 ± 0.5 mm yr −1 respectively, mean ± 95% CI). Carbon concentration in the surface sediments was significantly reduced with a mean carbon loss of 2.21 Mg C ha −1 in the top 5 cm. Because sediment was lost from harvested plots, with a mean difference in elevation of 3 cm, an additional carbon loss of up to 2.54 Mg C ha −1 may have occurred over the 18 months. Seagrass removal had rapid and dramatic impacts on infauna and epifauna. There was a loss of diversity in harvested plots and a shift toward larger bodied, bioturbating species, with a significant increase in mounds and burrows. Buried seagrass litter decomposed significantly faster in the harvested compared with the control plots. Loss of seagrass therefore led to rapid changes in sediment dynamics and chemistry driven in part by significant alterations in the faunal community.

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Seagrass Removal Leads to Rapid Changes in Fauna and Loss of Carbon

et al. 2019

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“…Variability of sedimentary C org stocks has been associated with multiple interrelated biological and environmental factors: type of seagrass species 7 , depth and light availability 10,11 , landscape configuration 12 , physical disturbances 13 , wave height and turbidity 14 , and even faunal presence such as bioturbators and top predators 15,16 Most of these studies highlighted the type of carbon sources and the sediment grain size as the main factors influencing carbon storage in seagrass sediments, suggesting that the processes affecting these factors explain the high variability found in seagrass sedimentary C org stocks 17 .…”

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confidence: 99%

High variability of Blue Carbon storage in seagrass meadows at the estuary scale

Ricart

York

Bryant

et al. 2020

Sci Rep

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Seagrass meadows are considered important natural carbon sinks due to their capacity to store organic carbon (c org) in sediments. However, the spatial heterogeneity of carbon storage in seagrass sediments needs to be better understood to improve accuracy of Blue Carbon assessments, particularly when strong gradients are present. We performed an intensive coring study within a subtropical estuary to assess the spatial variability in sedimentary c org associated with seagrasses, and to identify the key factors promoting this variability. We found a strong spatial pattern within the estuary, from 52.16 mg c org cm −3 in seagrass meadows in the upper parts, declining to 1.06 mg C org cm −3 in seagrass meadows at the estuary mouth, despite a general gradient of increasing seagrass cover and seagrass habitat extent in the opposite direction. the sedimentary c org underneath seagrass meadows came principally from allochthonous (non-seagrass) sources (~70-90 %), while the contribution of seagrasses was low (~10-30 %) throughout the entire estuary. Our results showed that C org stored in sediments of seagrass meadows can be highly variable within an estuary, attributed largely to accumulation of fine sediments and inputs of allochthonous sources. Local features and the existence of spatial gradients must be considered in Blue carbon estimates in coastal ecosystems.

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“…Benthic invertebrates are abundant in mangrove forests and their bioturbation activities are essential to biogeochemical cycles, ultimately influencing the diagenesis of OC within soils (Aller 1982;Kristensen and Alongi 2006;Kristensen et al 2008). Bioturbation has only recently been considered important for OC dynamics in coastal wetland soils, with growing evidence that large benthic bioturbators may increase or decrease soil carbon stocks (Andreetta et al 2014;Atwood et al 2015;Mehring et al 2017;Thomson et al 2019). Increased remineralization of soil carbon may occur when bioturbation increases soil oxygen supply, whereas burial of plant detritus into deep anoxic soil layers by benthic fauna may increase OC sequestration (Lee 1998;Kristensen et al 2008;Andreetta et al 2014;).…”

mentioning

confidence: 99%

Land use impacts on benthic bioturbation potential and carbon burial in Brazilian mangrove ecosystems

Bernardino

Sanders

Bissoli

et al. 2020

Limnology & Oceanography

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The potential of Blue Carbon as an integral part of global climate change adaptation and mitigation strategies requires quantification of drivers and rates of organic carbon (OC) burial and storage. However, there is limited recognition of how land use impacts benthic assemblages, their bioturbation potential, and OC burial in mangrove forests and tidal flats. Here we evaluated the effects of mangrove deforestation on benthic bioturbation potential (BPc), sediment accretion rates (SARs), and OC and total nitrogen (TN) burial in mangrove soils and tidal flat sediments from three estuaries in tropical Brazil. SARs based on 210 Pb dating varied significantly among undisturbed estuaries (2.1-18.6 mm yr −1) and the OC and TN burial rates were respectively 46% and 16% higher than global averages. The cleared mangrove sites had a twofold lower SAR, 40-fold lower OC burial, and over 100-fold lower TN burial when compared to undisturbed forests, revealing the pervasive impacts of land use. Variation in benthic assemblage structure and BPc among sites suggests that the composition and activity of macrofaunal communities may facilitate OC burial in some cases, yet the global extent and significance of bioturbation requires further study. Our work reveals a strong spatial variability in C burial in undisturbed mangrove forests and a decreased capacity of mangroves to accumulate C and sediments due to land use effects.

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Bioturbator‐stimulated loss of seagrass sediment carbon stocks

Cited by 29 publications

References 76 publications

Seagrass Removal Leads to Rapid Changes in Fauna and Loss of Carbon

Seagrass Removal Leads to Rapid Changes in Fauna and Loss of Carbon

High variability of Blue Carbon storage in seagrass meadows at the estuary scale

Land use impacts on benthic bioturbation potential and carbon burial in Brazilian mangrove ecosystems

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