Predictive mapping of organic carbon stocks and accumulation rates in surficial sediments of the Canadian continental margin

Epstein, Graham; Fuller, Susanna D.; Hingmire, Dipti; Myers, Paul G.; Peña, Angelica; Pennelly, Clark; Baum, Julia K.

doi:10.5194/essd-2023-295

Cited by 2 publications

(1 citation statement)

References 62 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…The sediment map effectively classified the hard and soft substrate (F1=0.91) and significantly refined our 375 understanding of the detailed distribution of the organic carbon. Previous studies have applied similar machine learning modelling approaches with success (Stephen and Diesing et al, 2015;Misiuk et al, 2019;Mitchell et al, 2019;Epstein et al 2023). Our results further demonstrate that this approach is suitable for mapping benthic substrates where high-resolution MBES data sets and suitable sediment ground-truthing are available.…”

Section: Nosupporting

confidence: 69%

Seafloor sediment characterization to improve estimate of organic carbon standing stocks in continental shelves

Brenan,

Kienast,

Maselli

et al. 2024

Preprint

View full text Add to dashboard Cite

Abstract. Continental shelf sediments contain some of the largest stocks of organic carbon (OC) on Earth and play a vital role in influencing the global carbon cycle. Quantifying how much OC is stored in shelf sediments and determining its residence time is key to assessing how human activities can accelerate the process of OC remineralization into carbon dioxide. Spatial variations in terrestrial carbon stocks are well studied and mapped at high resolution, but our knowledge of the distribution of marine OC in different seafloor settings is still very limited, particularly in the highly dynamic and spatially variable shelf environments. The lack of knowledge reduces our ability to understand and predict how much and for how long oceans sequester CO2. In this study, we use high-resolution multibeam echosounder (MBES) data from the Eastern Shore Islands offshore Nova Scotia (Canada), combined with OC measurements from discrete samples, to assess the distribution of OC content in seafloor sediments. We derive three different spatial estimates of organic carbon: i) assuming a homogenous seafloor the carbon stock estimates were scaled to the entire study region; ii) using a high-resolution substrate map, the estimates were scaled to the areas of soft substrate only, and, finally, iii) using Empirical Bayesian Regression Kriging (EBRK) regression prediction within the area of soft substrate, carbon stock estimates in areas of soft substrate were refined to account for spatial variability in the concentration of OC. These three distinct spatial models yielded dramatically different estimates of average standing stock of OC in our study area, 1275, 259 and 203 Mt of OC respectively. Our study demonstrates that high-resolution mapping is critically important for improved estimates of OC stocks on continental shelves, and to the identification of carbon hotspots that need to be considered in seabed management and climate mitigation strategies.

show abstract

Section: Nosupporting

confidence: 69%

Seafloor sediment characterization to improve estimate of organic carbon standing stocks in continental shelves

Brenan,

Kienast,

Maselli

et al. 2024

Preprint

View full text Add to dashboard Cite

show abstract

Predictive mapping of organic carbon stocks in surficial sediments of the Canadian continental margin

Epstein,

Fuller,

Hingmire

et al. 2024

Earth Syst. Sci. Data

Self Cite

View full text Add to dashboard Cite

Abstract. Quantification and mapping of surficial seabed sediment organic carbon have wide-scale relevance for marine ecology, geology and environmental resource management, with carbon densities and accumulation rates being a major indicator of geological history, ecological function and ecosystem service provisioning, including the potential to contribute to nature-based climate change mitigation. While global analyses can appear to provide a definitive understanding of the spatial distribution of sediment carbon, regional maps may be constructed at finer resolutions and can utilise targeted data syntheses and refined spatial data products and therefore have the potential to improve these estimates. Here, we report a national systematic review of data on organic carbon content in seabed sediments across Canada and combine this with a synthesis and unification of the best available data on sediment composition, seafloor morphology, hydrology, chemistry and geographic settings within a machine learning mapping framework. Predictive quantitative maps of mud content, dry bulk density, organic carbon content and organic carbon density were produced along with cell-specific estimates of their uncertainty at 200 m resolution across 4 489 235 km2 of the Canadian continental margin (92.6 % of the seafloor area above 2500 m) (https://doi.org/10.5683/SP3/ICHVVA, Epstein et al., 2024). Fine-scale variation in carbon stocks was identified across the Canadian continental margin, particularly in the Pacific Ocean and Atlantic Ocean regions. Overall, we estimate the standing stock of organic carbon in the top 30 cm of surficial seabed sediments across the Canadian shelf and slope to be 10.9 Gt (7.0–16.0 Gt). Increased empirical sediment data collection and higher precision in spatial environmental data layers could significantly reduce uncertainty and increase accuracy in these products over time.

show abstract

Predictive mapping of organic carbon stocks and accumulation rates in surficial sediments of the Canadian continental margin

Cited by 2 publications

References 62 publications

Seafloor sediment characterization to improve estimate of organic carbon standing stocks in continental shelves

Seafloor sediment characterization to improve estimate of organic carbon standing stocks in continental shelves

Predictive mapping of organic carbon stocks in surficial sediments of the Canadian continental margin

Contact Info

Product

Resources

About