Your search keyword '"Racault MF"' showing total 8 results

1. Framework for understanding marine ecosystem health

Author

Tett, P, primary, Gowen, RJ, additional, Painting, SJ, additional, Elliott, M, additional, Forster, R, additional, Mills, DK, additional, Bresnan, E, additional, Capuzzo, E, additional, Fernandes, TF, additional, Foden, J, additional, Geider, RJ, additional, Gilpin, LC, additional, Huxham, M, additional, McQuatters-Gollop, AL, additional, Malcolm, SJ, additional, Saux-Picart, S, additional, Platt, T, additional, Racault, MF, additional, Sathyendranath, S, additional, van der Molen, J, additional, and Wilkinson, M, additional

Published

2013

2. Towards an end-to-end analysis and prediction system for weather, climate, and Marine applications in the Red Sea

Author

Hoteit, I, Abualnaja, Y, Afzal, S, Ait-El-Fquih, B, Akylas, T, Antony, C, Dawson, C, Asfahani, K, Brewin, RJ, Cavaleri, L, Cerovecki, I, Cornuelle, B, Desamsetti, S, Attada, R, Dasari, H, Sanchez-Garrido, J, Genevier, L, El Gharamti, M, Gittings, JA, Gokul, E, Gopalakrishnan, G, Guo, D, Hadri, B, Hadwiger, M, Hammoud, MA, Hendershott, M, Hittawe, M, Karumuri, A, Knio, O, Köhl, A, Kortas, S, Krokos, G, Kunchala, R, Issa, L, Lakkis, I, Langodan, S, Lermusiaux, P, Luong, T, Ma, J, Le Maitre, O, Mazloff, M, El Mohtar, S, Papadopoulos, VP, Platt, T, Pratt, L, Raboudi, N, Racault, MF, Raitsos, DE, Razak, S, Sanikommu, S, Sathyendranath, S, Sofianos, S, Subramanian, A, Sun, R, Titi, E, Toye, H, Triantafyllou, G, Tsiaras, K, Vasou, P, Viswanadhapalli, Y, Wang, Y, Yao, F, Zhan, P, and Zodiatis, G

Subjects

13 Climate Action, 13. Climate action, 37 Earth Sciences, 7 Affordable and Clean Energy, 14. Life underwater, 3708 Oceanography, 7. Clean energy, 6. Clean water

Abstract

The Red Sea, home to the second-longest coral reef system in the world, is a vital resource for the Kingdom of Saudi Arabia. The Red Sea provides 90% of the Kingdom’s potable water by desalinization, supporting tourism, shipping, aquaculture, and fishing industries, which together contribute about 10%–20% of the country’s GDP. All these activities, and those elsewhere in the Red Sea region, critically depend on oceanic and atmospheric conditions. At a time of mega-development projects along the Red Sea coast, and global warming, authorities are working on optimizing the harnessing of environmental resources, including renewable energy and rainwater harvesting. All these require high-resolution weather and climate information. Toward this end, we have undertaken a multipronged research and development activity in which we are developing an integrated data-driven regional coupled modeling system. The telescopically nested components include 5-km- to 600-m-resolution atmospheric models to address weather and climate challenges, 4-km- to 50-m-resolution ocean models with regional and coastal configurations to simulate and predict the general and mesoscale circulation, 4-km- to 100-m-resolution ecosystem models to simulate the biogeochemistry, and 1-km- to 50-m-resolution wave models. In addition, a complementary probabilistic transport modeling system predicts dispersion of contaminant plumes, oil spill, and marine ecosystem connectivity. Advanced ensemble data assimilation capabilities have also been implemented for accurate forecasting. Resulting achievements include significant advancement in our understanding of the regional circulation and its connection to the global climate, development, and validation of long-term Red Sea regional atmospheric–oceanic–wave reanalyses and forecasting capacities. These products are being extensively used by academia, government, and industry in various weather and marine studies and operations, environmental policies, renewable energy applications, impact assessment, flood forecasting, and more.

3. Methylmercury contamination in Mediterranean seafood: Exposure assessment and cost of illness implications.

Author

Kennedy J, Calikanzaros E, Landrigan PJ, Badot PM, Cinar M, Safa A, Schomaker RM, Lloret J, Raps H, Racault MF, Hilmi N, and Bottein MYD

Abstract

Methylmercury (MeHg) is a widespread contaminant that bioaccumulates in marine food webs, including those in the Mediterranean sea. It poses serious health risks, especially to developing infants and children, where exposure can cause neurological damage and developmental delays. In addition to health concerns, high MeHg levels in seafood can lead to economic losses through cognitive impairments that reduce productivity. Despite seafood being a dietary staple in Mediterranean countries, the full extent of MeHg's health and economic impacts remains underexplored, especially with the rising international trade. This study aims to (a) estimate MeHg exposures in Mediterranean populations from consumption of Mediterranean seafood and (b) quantify the economic costs associated with MeHg intake. We assessed population exposures in Mediterranean countries by combining a highly granular seafood supply data on Aquatic Resource Trade in Species (ARTIS), alongside Global Dietary Database (GDD) and review of MeHg levels in Mediterranean seafood. The economic cost was then derived by linking MeHg intake to productivity losses associated with cognitive deficits. As a result, we estimate that Mediterranean countries experience over €10 billion in annual economic losses due to IQ-related productivity decline associated with MeHg exposure from consuming seafood sourced from various fishing areas of the Mediterranean Sea. The novelty of this research lies in its transdisciplinary approach to MeHg impact assessment that incorporates highly detailed seafood supply data with dietary surveys, and scientific literature to provide a more realistic and detailed view of MeHg exposures and the associated cost-of illness from local seafood consumption accross Mediterranean countries. These findings highlight a critical aspect of MeHg management: while international trade can mitigate local exposure by providing access to less-contaminated imports, it simultaneously exports the contamination burden to other regions. This duality emphasizes the importance of global cooperation in addressing seafood safety and managing transboundary MeHg risks., Competing Interests: Declaration of competing interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2024. Published by Elsevier B.V.)

Published

2024

4. Ocean mover's distance: using optimal transport for analysing oceanographic data.

Author

Hyun S, Mishra A, Follett CL, Jonsson B, Kulk G, Forget G, Racault MF, Jackson T, Dutkiewicz S, Müller CL, and Bien J

Abstract

Remote sensing observations from satellites and global biogeochemical models have combined to revolutionize the study of ocean biogeochemical cycling, but comparing the two data streams to each other and across time remains challenging due to the strong spatial-temporal structuring of the ocean. Here, we show that the Wasserstein distance provides a powerful metric for harnessing these structured datasets for better marine ecosystem and climate predictions. The Wasserstein distance complements commonly used point-wise difference methods such as the root-mean-squared error, by quantifying differences in terms of spatial displacement in addition to magnitude. As a test case, we consider chlorophyll (a key indicator of phytoplankton biomass) in the northeast Pacific Ocean, obtained from model simulations, in situ measurements, and satellite observations. We focus on two main applications: (i) comparing model predictions with satellite observations, and (ii) temporal evolution of chlorophyll both seasonally and over longer time frames. The Wasserstein distance successfully isolates temporal and depth variability and quantifies shifts in biogeochemical province boundaries. It also exposes relevant temporal trends in satellite chlorophyll consistent with climate change predictions. Our study shows that optimal transport vectors underlying the Wasserstein distance provide a novel visualization tool for testing models and better understanding temporal dynamics in the ocean., (© 2022 The Authors.)

Published

2022

5. Climate Precursors of Satellite Water Marker Index for Spring Cholera Outbreak in Northern Bay of Bengal Coastal Regions.

Author

Ogata T, Racault MF, Nonaka M, and Behera S

Subjects

Bays, Disease Outbreaks, Humans, Seasons, Water, Cholera epidemiology

Abstract

Cholera is a water-borne infectious disease that affects 1.3 to 4 million people, with 21,000 to 143,000 reported fatalities each year worldwide. Outbreaks are devastating to affected communities and their prospects for development. The key to support preparedness and public health response is the ability to forecast cholera outbreaks with sufficient lead time. How Vibrio cholerae survives in the environment outside a human host is an important route of disease transmission. Thus, identifying the environmental and climate drivers of these pathogens is highly desirable. Here, we elucidate for the first time a mechanistic link between climate variability and cholera (Satellite Water Marker; SWM) index in the Bengal Delta, which allows us to predict cholera outbreaks up to two seasons earlier. High values of the SWM index in fall were associated with above-normal summer monsoon rainfalls over northern India. In turn, these correlated with the La Niña climate pattern that was traced back to the summer monsoon and previous spring seasons. We present a new multi-linear regression model that can explain 50% of the SWM variability over the Bengal Delta based on the relationship with climatic indices of the El Niño Southern Oscillation, Indian Ocean Dipole, and summer monsoon rainfall during the decades 1997-2016. Interestingly, we further found that these relationships were non-stationary over the multi-decadal period 1948-2018. These results bear novel implications for developing outbreak-risk forecasts, demonstrating a crucial need to account for multi-decadal variations in climate interactions and underscoring to better understand how the south Asian summer monsoon responds to climate variability.

Published

2021

6. Cholera Risk: A Machine Learning Approach Applied to Essential Climate Variables.

Author

Campbell AM, Racault MF, Goult S, and Laurenson A

Subjects

Ecosystem, Humans, India epidemiology, Machine Learning, Oceans and Seas, Cholera epidemiology

Abstract

Oceanic and coastal ecosystems have undergone complex environmental changes in recent years, amid a context of climate change. These changes are also reflected in the dynamics of water-borne diseases as some of the causative agents of these illnesses are ubiquitous in the aquatic environment and their survival rates are impacted by changes in climatic conditions. Previous studies have established strong relationships between essential climate variables and the coastal distribution and seasonal dynamics of the bacteria Vibrio cholerae , pathogenic types of which are responsible for human cholera disease. In this study we provide a novel exploration of the potential of a machine learning approach to forecast environmental cholera risk in coastal India, home to more than 200 million inhabitants, utilising atmospheric, terrestrial and oceanic satellite-derived essential climate variables. A Random Forest classifier model is developed, trained and tested on a cholera outbreak dataset over the period 2010-2018 for districts along coastal India. The random forest classifier model has an Accuracy of 0.99, an F1 Score of 0.942 and a Sensitivity score of 0.895, meaning that 89.5% of outbreaks are correctly identified. Spatio-temporal patterns emerged in terms of the model's performance based on seasons and coastal locations. Further analysis of the specific contribution of each Essential Climate Variable to the model outputs shows that chlorophyll-a concentration, sea surface salinity and land surface temperature are the strongest predictors of the cholera outbreaks in the dataset used. The study reveals promising potential of the use of random forest classifiers and remotely-sensed essential climate variables for the development of environmental cholera-risk applications. Further exploration of the present random forest model and associated essential climate variables is encouraged on cholera surveillance datasets in other coastal areas affected by the disease to determine the model's transferability potential and applicative value for cholera forecasting systems.

Published

2020

7. Evaluating tropical phytoplankton phenology metrics using contemporary tools.

Author

Gittings JA, Raitsos DE, Kheireddine M, Racault MF, Claustre H, and Hoteit I

Subjects

Databases, Factual, Environmental Monitoring methods, Indian Ocean, Satellite Imagery, Seasons, Tropical Climate, Chlorophyll A, Phytoplankton physiology, Remote Sensing Technology methods

Abstract

The timing of phytoplankton growth (phenology) in tropical oceans is a crucial factor influencing the survival rates of higher trophic levels, food web structure and the functioning of coral reef ecosystems. Phytoplankton phenology is thus categorised as an 'ecosystem indicator', which can be utilised to assess ecosystem health in response to environmental and climatic perturbations. Ocean-colour remote sensing is currently the only technique providing global, long-term, synoptic estimates of phenology. However, due to limited available in situ datasets, studies dedicated to the validation of satellite-derived phenology metrics are sparse. The recent development of autonomous oceanographic observation platforms provides an opportunity to bridge this gap. Here, we use satellite-derived surface chlorophyll-a (Chl-a) observations, in conjunction with a Biogeochemical-Argo dataset, to assess the capability of remote sensing to estimate phytoplankton phenology metrics in the northern Red Sea - a typical tropical marine ecosystem. We find that phenology metrics derived from both contemporary platforms match with a high degree of precision (within the same 5-day period). The remotely-sensed surface signatures reflect the overall water column dynamics and successfully capture Chl-a variability related to convective mixing. Our findings offer important insights into the capability of remote sensing for monitoring food availability in tropical marine ecosystems, and support the use of satellite-derived phenology as an ecosystem indicator for marine management strategies in regions with limited data availability.

Published

2019

8. Phenological Responses to ENSO in the Global Oceans.

Author

Racault MF, Sathyendranath S, Menon N, and Platt T

Abstract

Phenology relates to the study of timing of periodic events in the life cycle of plants or animals as influenced by environmental conditions and climatic forcing. Phenological metrics provide information essential to quantify variations in the life cycle of these organisms. The metrics also allow us to estimate the speed at which living organisms respond to environmental changes. At the surface of the oceans, microscopic plant cells, so-called phytoplankton, grow and sometimes form blooms, with concentrations reaching up to 100 million cells per litre and extending over many square kilometres. These blooms can have a huge collective impact on ocean colour, because they contain chlorophyll and other auxiliary pigments, making them visible from space. Phytoplankton populations have a high turnover rate and can respond within hours to days to environmental perturbations. This makes them ideal indicators to study the first-level biological response to environmental changes. In the Earth's climate system, the El Niño-Southern Oscillation (ENSO) dominates large-scale inter-annual variations in environmental conditions. It serves as a natural experiment to study and understand how phytoplankton in the ocean (and hence the organisms at higher trophic levels) respond to climate variability. Here, the ENSO influence on phytoplankton is estimated through variations in chlorophyll concentration, primary production and timings of initiation, peak, termination and duration of the growing period. The phenological variabilities are used to characterise phytoplankton responses to changes in some physical variables: sea surface temperature, sea surface height and wind. It is reported that in oceanic regions experiencing high annual variations in the solar cycle, such as in high latitudes, the influence of ENSO may be readily measured using annual mean anomalies of physical variables. In contrast, in oceanic regions where ENSO modulates a climate system characterised by a seasonal reversal of the wind forcing, such as the monsoon system in the Indian Ocean, phenology-based mean anomalies of physical variables help refine evaluation of the mechanisms driving the biological responses and provide a more comprehensive understanding of the integrated processes., (© The Author(s) 2016.)

Published

2017