Your search keyword '"Odile Crabeck"' showing total 4 results

1. Upward transport of bottom-ice dimethyl sulfide during advanced melting of arctic first-year sea ice

Author

Margaux Gourdal, Odile Crabeck, Martine Lizotte, Virginie Galindo, Michel Gosselin, Marcel Babin, Michael Scarratt, and Maurice Levasseur

Subjects

DMS, Sea ice, Gas exchanges, Biogenic gas fluxes, Arctic, Environmental sciences, GE1-350

Abstract

This paper presents the first empirical estimates of dimethyl sulfide (DMS) gas fluxes across permeable sea ice in the Arctic. DMS is known to act as a major potential source of aerosols that strongly influence the Earth’s radiative balance in remote marine regions during the ice-free season. Results from a sampling campaign, undertaken in 2015 between June 2 and June 28 in the ice-covered Western Baffin Bay, revealed the presence of high algal biomass in the bottom 0.1-m section of sea ice (21 to 380 μg Chl 'a' L–1) combined with the presence of high DMS concentrations (212–840 nmol L–1). While ice algae acted as local sources of DMS in bottom sea ice, thermohaline changes within the brine network, from gravity drainage to vertical stabilization, exerted strong control on the distribution of DMS within the interior of the ice. We estimated both the mean DMS molecular diffusion coefficient in brine (5.2 × 10–5 cm2 s–1 ± 51% relative S.D., n = 10) and the mean bulk transport coefficient within sea ice (33 × 10–5 cm2 s–1 ± 41% relative S.D., n = 10). The estimated DMS fluxes ± S.D. from the bottom ice to the atmosphere ranged between 0.47 ± 0.08 μmol m–2 d–1 (n = 5, diffusion) and 0.40 ± 0.15 μmol m–2 d–1 (n = 5, bulk transport) during the vertically stable phase. These fluxes fall within the lower range of direct summer sea-to-air DMS flfluxes reported in the Arctic. Our results indicate that upward transport of DMS, from the algal-rich bottom of first-year sea ice through the permeable sea ice, may represent an important pathway for this biogenic gas toward the atmosphere in ice-covered oceans in spring and summer.

Published

2019

2. Application of Simulation Chambers to Investigate Interfacial Processes

Author

Peter A. Alpert, François Bernard, Paul Connolly, Odile Crabeck, Christian George, Jan Kaiser, Ottmar Möhler, Dennis Niedermeier, Jakub Nowak, Sébastien Perrier, Paul Seakins, Frank Stratmann, and Max Thomas

Abstract

Earlier chapters of this work have described procedures and protocols that are applicable to most chambers, this chapter has a slightly different focus; we predominantly consider multiphase processes where the applications are on phase transfer of chemical species rather than chemical reactions and the processes are generally occurring in highly specialized chambers. Three areas are described. Firstly, cloud formation processes; here, precise control of physical and thermodynamic properties is required to generate reproducible results. The second area examined is the air/sea interface, looking at the formation of aerosols from nonanoic acid as a surfactant with humic acid as a photosensitizer. The final apparatus described is the Roland von Glasow sea-ice chamber where a detailed protocol for the reproducible formation of sea-ice is given along with an outlook of future work. The systems studied in all three sections are characterized by difficulties in making detailed in situ observations in the real world, either due to the transitory nature of systems or the practical difficulties in accessing the systems. While these specialized simulation chambers may not perfectly reproduce conditions in the real world, the chambers do provide more facile opportunities for making extended and reproducible measurements to investigate fundamental physical and chemical processes, at significantly lower costs.

Published

2023

3. Methods for Interpreting the Partitioning and Fate of Petroleum Hydrocarbons in a Sea Ice Environment

Author

Durell S. Desmond, Diana Saltymakova, Odile Crabeck, Georg Schreckenbach, James D. Xidos, David G. Barber, Dustin Isleifson, and Gary A. Stern

Subjects

Petroleum, Solubility, Ice Cover, Physical and Theoretical Chemistry, Ecosystem, Hydrocarbons

Abstract

Decreases in Arctic Sea ice extent and thickness have led to more open ice conditions, encouraging both shipping traffic and oil exploration within the northern Arctic. As a result, the increased potential for accidental releases of crude oil or fuel into the Arctic environment threatens the pristine marine environment, its ecosystem, and local inhabitants. Thus, there is a need to develop a better understanding of oil behavior in a sea ice environment on a microscopic level. Computational quantum chemistry was used to simulate the effects of evaporation, dissolution, and partitioning within sea ice. Vapor pressures, solubilities, octanol-water partition coefficients, and molecular volumes were calculated using quantum chemistry and thermodynamics for pure liquid solutes (oil constituents) of interest. These calculations incorporated experimentally measured temperatures and salinities taken throughout an oil-in-ice mesocosm experiment conducted at the University of Manitoba in 2017. Their potential for interpreting the relative movements of oil constituents was assessed. Our results suggest that the relative movement of oil constituents is influenced by differences in physical properties. Lighter molecules showed a greater tendency to be controlled by brine advection processes due to their greater solubility. Molecules which are more hydrophobic were found to concentrate in areas of lower salt concentration.

Published

2022

4. Pollution in the Arctic Ocean: An overview of multiple pressures and implications for ecosystem services

Author

Bryony L. Townhill, Efstathios Reppas-Chrysovitsinos, Roxana Sühring, Crispin J. Halsall, Elena Mengo, Tina Sanders, Kirsten Dähnke, Odile Crabeck, Jan Kaiser, and Silvana N. R. Birchenough

Subjects

Ecology, Arctic Regions, Anthropogenic Effects, Oceans and Seas, Geography, Planning and Development, General Medicine, Ecopath, Modelling, Management, Policy, Contaminants, Environmental Chemistry, Humans, Hunting, Chemicals, Changing Arctic Ocean, geographic locations, Ecosystem

Abstract

The Arctic is undergoing unprecedented change. Observations and models demonstrate significant perturbations to the physical and biological systems. Arctic species and ecosystems, particularly in the marine environment, are subject to a wide range of pressures from human activities, including exposure to a complex mixture of pollutants, climate change and fishing activity. These pressures affect the ecosystem services that the Arctic provides. Current international policies are attempting to support sustainable exploitation of Arctic resources with a view to balancing human wellbeing and environmental protection. However, assessments of the potential combined impacts of human activities are limited by data, particularly related to pollutants, a limited understanding of physical and biological processes, and single policies that are limited to ecosystem-level actions. This manuscript considers how, when combined, a suite of existing tools can be used to assess the impacts of pollutants in combination with other anthropogenic pressures on Arctic ecosystems, and on the services that these ecosystems provide. Recommendations are made for the advancement of targeted Arctic research to inform environmental practices and regulatory decisions.

Published

2021