Global change effects on decomposition processes in tidal wetlands: implications from a global survey using standardized litter

Müeller, Peter R.; Schile-Beers, Lisa; Mozdzer, Thomas J.; Chmura, Gail L.; Dinter, Thomas; Kuzyakov, Yakov; Groot, A.V. de; Esselink, Peter; Smit, Christian; D’Alpaos, Andrea; Ibáñez, Carles; Lazarus, Magdalena; Neumeier, Urs; Johnson, Beverly J.; Baldwin, Andrew H.; Yarwood, Stephanie A.; Montemayor, Diana I.; Yang, Zhongyi; Wu, Jihua; Jensen, Kai Arne; Nolte, Stefanie

doi:10.5194/bg-2017-533

Cited by 2 publications

(3 citation statements)

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“…While our study did not partition R eco between microbial and autotrophic respiration, the most parsimonious explanation for our results is that changes in R eco were due to changes in soil microbial activity, given the similar levels of above and belowground biomass in our study ( Figure 2). In addition, previous research at our site has demonstrated that fertilization with NO 3 -, which is a strong electron acceptor, has stimulated denitrification (Koop-Jakobsen and Giblin 2010), increased litter respiration (Deegan et al 2012), and decreased soil organic matter stabilization (Mueller et al 2017). Work in another temperate tidal salt marsh, the Great Sippewisset Marsh, has demonstrated that N enrichment can alter the active soil microbial community to favor denitrifying bacteria (Peng et al 2016) and increase R eco (Martin et al 2018).…”

Section: Discussionmentioning

confidence: 64%

Nitrogen enrichment alters carbon fluxes in a New England salt marsh

Geoghegan

Caplan

Leech

et al. 2018

Ecosyst Health Sustain

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Introduction: Nitrogen enrichment of coastal salt marshes can induce feedbacks that alter ecosystem-level processes including primary production and carbon sequestration. Despite the rising interest in coastal blue carbon, the effects of chronic nutrient enrichment on blue carbon processes have rarely been measured in the context of experimental fertilization. Here, we examined the ecosystem-level effects of nitrate (NO 3 −) enrichment on the greenhouse gas dynamics of a Spartina alterniflora-dominated salt marsh. We measured CO 2 and CH 4 fluxes using static chambers through two growing seasons in a salt marsh that was nitrogen-enriched for 13 years and compared fluxes to those from a reference marsh. Outcomes: We found that nitrogen enrichment increased gross primary productivity (GPP) by 7.7% and increased ecosystem respiration (R eco) by 20.8%. However, nitrogen enrichment had no discernible effect on net ecosystem exchange (NEE). Taken together, these results suggest that nitrogen-induced stimulation of R eco could transform this salt marsh from a carbon sink into a source of carbon to the atmosphere. Conclusion: Our results complement prior findings of nitrogen enrichment weakening soil structure and organic matter stability in tidal salt marshes, suggesting that increased nutrient inputs have the potential to alter the carbon storage function of these ecosystems through enhanced microbial respiration of previously sequestered carbon.

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Section: Discussionmentioning

confidence: 64%

Nitrogen enrichment alters carbon fluxes in a New England salt marsh

Geoghegan

Caplan

Leech

et al. 2018

Ecosyst Health Sustain

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“…Tremendous efforts at mitigating N loading to coastal waters have improved conditions in some regions (Zedler 2000, Warren et al 2002, however, worldwide, many salt marshes continue to experience chronic nutrient enrichment (Bricker et al 2008. The implications of this nutrient enrichment for C storage in salt marshes remain unclear, with some studies documenting an increase in primary production (Valiela et al 1975, Morris et al 1991, Morris et al 2013, and others indicating decreased belowground biomass (Langley et al 2009, Watson et al 2014, increased respiration of OM (Wigand et al 2009, Watson et al 2014, and decreased sediment stability , Mueller et al 2018).…”

Section: Introductionmentioning

confidence: 99%

“…Although nitrate is typically limiting in coastal waters (Ryther & Dunstan 1979), nutrient enrichment from fertilizer production, agricultural and urban runoff, enriched groundwater, and atmospheric deposition may increase its availability to sediment microbes . Increased supplies of nitrate can stimulate respiration of belowground OM by providing additional reducing capacity to the system (Bulseco-McKim et al In review), which can lead to lower sediment stability and potential marsh collapse , Mueller et al 2018.…”

Section: Introductionmentioning

confidence: 99%

Nitrate as an electron acceptor in microbial decomposition of salt marsh sediment organic matter and implications for carbon storage

Bulseco-McKim¹

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I could not have had more supportive, encouraging advisors throughout my academic career thus far. First and foremost, I thank Jennifer Bowen for teaching me how to be resilient, both as a scientist and as a human. Her ability to think critically and quickly are skills I will always strive to match. More importantly, Jen has helped me persevere through times of extreme anxiety and self-doubt, and for that I will be forever grateful. I also thank my co-advisor, Anne Giblin, whose kindness and willingness to help are unmatched by any other individual I have ever met. She is an exceptional role model for women in science everywhere, and helped to shape the clarity of my work. Thank you to the rest of my committee at Northeastern University, Randall Hughes, Aron Stubbins, and Amy Mueller, who contributed insightful thought to my dissertation. I would also like to thank my UMass committee, including Bob Chen and Crystal Schaaf, who both played a critical role in the initial development of my proposal and critical thinking. Lastly, a sincere mahalo to my undergraduate advisor, Tracy Wiegner, for being my biggest cheerleader throughout the years.

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Global change effects on decomposition processes in tidal wetlands: implications from a global survey using standardized litter

Cited by 2 publications

References 34 publications

Nitrogen enrichment alters carbon fluxes in a New England salt marsh

Nitrogen enrichment alters carbon fluxes in a New England salt marsh

Nitrate as an electron acceptor in microbial decomposition of salt marsh sediment organic matter and implications for carbon storage

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