Environmental Controls, Emergent Scaling, and Predictions of Greenhouse Gas (GHG) Fluxes in Coastal Salt Marshes

Abdul-Aziz, O. I.; Ishtiaq, K. S.; Tang, Jianwu; Moseman‐Valtierra, Serena; Kroeger, Kevin D.; Gonneea, M. E.; Mora, Jordan W.; Morkeski, K.

doi:10.1029/2018jg004556

Cited by 52 publications

(55 citation statements)

References 138 publications

(177 reference statements)

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“…Our data show a direct and strong relationship between the levels of dissolved methane, organic matter content and water temperature, as it has been observed in other brackish coastal wetlands (Welti et al, 2017). Methanogenesis is substantially driven by temperature (Martin and Moseman-Valtierra, 2017) and it is therefore the most dominant environmental driver of CH 4 emissions in wetlands (Yvon-Durocher et al, 2014) specifically in coastal salt marshes (Abdul-Aziz et al, 2018). The overall pattern found here therefore suggests a methanogenesis control by temperature in the sediment, which has been described as muddy with numerous stems and roots and scarce micro-fauna (Ruiz et al, 2004).…”

Section: Sources Of Ch 4 In Doñana Salt Marshessupporting

confidence: 79%

“…The overall pattern found here therefore suggests a methanogenesis control by temperature in the sediment, which has been described as muddy with numerous stems and roots and scarce micro-fauna (Ruiz et al, 2004). In addition, vegetation in the marshes may have supported a methanogens population that could contribiute to an increase of CH 4 concentrations during warmer conditions, which has been found in Spartina dominated wetlands (Burke et al, 2002;Abdul-Aziz et al, 2018). The organic-matter rich sediment in conjunction with the organic inputs from the heterotrophic Guadalquivir estuary (Flecha et al, 2015) and those generated in situ by the phytoplankton productivity, as indicated by the association found between Chl a and DOC, provide optimal conditions for sedimentary methanogenesis to proceed, with temperature acting as a major regulating driver.…”

Section: Sources Of Ch 4 In Doñana Salt Marshessupporting

confidence: 50%

“…Few studies have quantified and investigated air-water CH 4 exchange and dynamics in tidal flats (Dean et al, 2018). The fluxes measured in our study are slightly lower than those observed in subtropical tidal wetlands (Tong et al, 2013;Welti et al, 2017), coherent with a temperature control on methanogenesis (Abdul-Aziz et al, 2018). Lower emissions can therefore be expected from temperate coastal wetlands compared to tropical and subtropical coastal wetlands.…”

Section: Ch 4 Emissions From the Doñana Salt Marshescontrasting

confidence: 48%

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Methane Emissions From the Salt Marshes of Doñana Wetlands: Spatio-Temporal Variability and Controlling Factors

et al. 2019

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Section: Sources Of Ch 4 In Doñana Salt Marshessupporting

confidence: 79%

Section: Sources Of Ch 4 In Doñana Salt Marshessupporting

confidence: 50%

Section: Ch 4 Emissions From the Doñana Salt Marshescontrasting

confidence: 48%

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Methane Emissions From the Salt Marshes of Doñana Wetlands: Spatio-Temporal Variability and Controlling Factors

et al. 2019

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“…The complexity of the salt marsh response may also be related to tidal forcing, which is a control on water availability and solute content that exists in salt marshes, but not terrestrial upland ecosystems or even most wetlands. In salt marshes, rates of productivity and GHG fluxes vary between high and low tides (Abdul-Aziz et al, 2018;Kathilankal et al, 2008;Moffett et al, 2010) and between the neap and spring tide astronomical extremes (Guo et al, 2009;Tong et al, 2013;this study). Therefore, the carbon cycling response of salt marshes to precipitation change likely depends on tidal context, with a given precipitation change potentially having different or even opposite effects depending on local tidal inundation regime and tidal phase.…”

Section: Ecosystem Responses To Precipitation Change and Their Driversmentioning

confidence: 91%

Salt Marsh Greenhouse Gas Fluxes and Microbial Communities Are Not Sensitive to the First Year of Precipitation Change

2019

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Changing precipitation patterns are predicted to alter ecosystem structure and function with potential carbon cycle feedbacks to climate change. Influenced by both land and sea, salt marshes are unique ecosystems and their productivity and respiration responses to precipitation change differ from those observed in terrestrial ecosystems. How salt marsh greenhouse gas fluxes and sediment microbial communities will respond to climate‐induced precipitation changes is largely unknown. We conducted 1‐year precipitation manipulation experiments in the Spartina patens (high marsh) zone of two salt marshes and quantified ecosystem functions at both and microbial community structure at one. Precipitation treatments (doubled rainfall, extreme drought, and seasonal intensification) had a significant, although transient, impact on porewater salinity following storms at both sites, but most site conditions (nutrient concentrations, sediment moisture, and temperature) were unaffected. Extreme drought led to a subtle change in microbial community structure, but most ecosystem functions (primary productivity, litter decomposition, and greenhouse gas fluxes) were not affected by precipitation changes. The absence of ecosystem function change indicates functional redundancy (under extreme drought) and resistance (under doubled precipitation and seasonal intensification) exist in the microbial community. Our findings demonstrate that salt marsh ecosystems can maintain function (including ecosystem services like carbon sequestration) under even the most extreme precipitation change scenarios, due to resistance, resilience, and functional redundancy in the underlying microbial community.

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“…The seasonal change of daytime CO 2 uptake by wetland plants is mainly driven by temperature, photosynthetically active radiation, and day‐length (Moseman‐Valtierra et al, ). Previous studies reported that higher ambient temperature and light intensity could accelerate the activity of the primary C 4 photosynthetic enzyme (RuBisCO), resulting in higher CO 2 uptake (Abdul‐Aziz et al, ; Guo et al, ; Inglett et al, ). Moreover, methanogenesis is substantially driven by temperature (Martin & Moseman‐Valtierra, ), which could contribute to higher CH 4 emission during high temperatures.…”

Section: Discussionmentioning

confidence: 99%

Enhanced Carbon Uptake and Reduced Methane Emissions in a Newly Restored Wetland

et al. 2020

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Wetlands play an important role in reducing global warming potential in response to global climate change. Unfortunately, due to the effects of human disturbance and natural erosion, wetlands are facing global extinction. It is essential to implement engineering measures to restore damaged wetlands. However, the carbon sink capacity of restored wetlands is unclear. We examined the seasonal change of greenhouse gas emissions in both restored wetland and natural wetland and then evaluated the carbon sequestration capacity of the restored wetland. We found that (1) the carbon sink capacity of the restored wetland showed clear daily and seasonal change, which was affected by light intensity, air temperature, and vegetation growth, and (2) the annual daytime (8-18 hr) sustained-flux global warming potential was −11.23 ± 4.34 kg CO 2 m −2 y −1 , representing a much larger carbon sink than natural wetland (−5.04 ± 3.73 kg CO 2 m −2 y −1 ) from April to December. In addition, the results showed that appropriate tidal flow management may help to reduce CH 4 emission in wetland restoration. Thus, we proposed that the restored coastal wetland, via effective engineering measures, reliably acted as a large net carbon sink and has the potential to help mitigate climate change. Key Points:• The main factors that influenced wetland greenhouse gas emissions were plant growth, water flow, and nitrogen loading • The restored wetland was a much stronger carbon sink than the natural wetland by maximizing CO 2 uptake and minimizing CH 4 emissions • Altering species composition and water flow as part of wetland restoration was an innovative strategy for mitigating climate change Supporting Information:• Supporting Information S1 , et al. (2020). Enhanced carbon uptake and reduced methane emissions in a newly restored wetland.

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Environmental Controls, Emergent Scaling, and Predictions of Greenhouse Gas (GHG) Fluxes in Coastal Salt Marshes

Cited by 52 publications

References 138 publications

Methane Emissions From the Salt Marshes of Doñana Wetlands: Spatio-Temporal Variability and Controlling Factors

Methane Emissions From the Salt Marshes of Doñana Wetlands: Spatio-Temporal Variability and Controlling Factors

Salt Marsh Greenhouse Gas Fluxes and Microbial Communities Are Not Sensitive to the First Year of Precipitation Change

Enhanced Carbon Uptake and Reduced Methane Emissions in a Newly Restored Wetland

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