Title | Salt marsh ecosystem restructuring enhances elevation resilience and carbon storage during accelerating relative sea-level rise |
Publication Type | Journal Article |
Year of Publication | 2019 |
Authors | Gonneea, MEagle, Maio, CV, Kroeger, KD, Hawkes, AD, Mora, J, Sullivan, R, Madsen, S, Buzard, RM, Cahill, N, Donnelly, JP |
Journal | Estuarine, Coastal and Shelf Science |
Volume | 217 |
Pagination | 56 - 68 |
Date Published | Jan-02-2019 |
ISSN | 02727714 |
Keywords | 14-Carbon, accretion, Carbon storage, Elevation, Salt marsh, Sea level index point, sea-level rise |
Abstract | Salt marshes respond to sea-level rise through a series of complex and dynamic bio-physical feedbacks. In this study, we found that sea-level rise triggered salt marsh habitat restructuring, with the associated vegetation changes enhancing salt marsh elevation resilience. A continuous record of marsh elevation relative to sea level that includes reconstruction of high-resolution, sub-decadal, marsh elevation over the past century, coupled with a lower-resolution 1500-year record, revealed that relative sea-level rose 1.5 ± 0.4 m, following local glacial isostatic adjustment (1.2 mm/yr). As sea-level rise has rapidly accelerated, the high marsh zone dropped 11 cm within the tidal frame since 1932, leading to greater inundation and a shift to flood- and salt-tolerant low marsh species. Once the marsh platform fell to the elevation favored by low-marsh Spartina alterniflora, the elevation stabilized relative to sea level. Currently low marsh accretion keeps pace with sea-level rise, while present day high marsh zones that have not transitioned to low marsh have a vertical accretion deficit. Greater biomass productivity, and an expanding subsurface accommodation space favorable for salt marsh organic matter preservation, provide a positive feed-back between sea-level rise and marsh platform elevation. Carbon storage was 46 ± 28 g C/m2/yr from 550 to 1800 CE, increasing to 129 ± 50 g C/m2/yr in the last decade. Enhanced carbon storage is controlled by vertical accretion rates, rather than soil carbon density, and is a direct response to anthropogenic eustatic sea-level rise, ultimately providing a negative feedback on climate warming. |
URL | https://linkinghub.elsevier.com/retrieve/pii/S0272771418306851 |
DOI | 10.1016/j.ecss.2018.11.003 |