Your search keyword '"Anesio, Alexandre M."' showing total 6 results

1. Molecular level characterization of supraglacial dissolved organic matter sources and exported pools the southern Greenland Ice Sheet.

Author

Doting, Eva L., Stevens, Ian T., Kellerman, Anne M., Rossel, Pamela E., Antony, Runa, McKenna, Amy M., Tranter, Martyn, Benning, Liane G., Spencer, Robert G. M., Hawkings, Jon R., and Anesio, Alexandre M.

Subjects

MELTWATER, ABLATION (Glaciology), GREENLAND ice, DISSOLVED organic matter, ICE sheets, ION cyclotron resonance spectrometry, EUPHOTIC zone

Abstract

During the ablation season, active microbial communities colonise large areas of the Greenland Ice Sheet surface and produce dissolved organic matter (DOM) that may be exported downstream by surface melt. Meltwater flow through the bare ice interfluvial area, characterized by a porous weathering crust, is slow (~ 10-2 m d-1), meaning that it presents a potential site for photochemical and/or microbial alteration of supraglacial DOM. Transformations of supraglacial DOM during transport through the supraglacial drainage system remain unexplored, limiting our understanding of supraglacial DOM inputs to downstream subglacial and coastal ecosystems. Here, we employ negative-ion electrospray ionization 21 tesla Fourier transform ion cyclotron resonance mass spectrometry to catalogue the molecular composition of DOM in supraglacial dark ice, weathering crust meltwater, and supraglacial stream water sampled in a hydrologically connected supraglacial micro- catchment to address this knowledge gap. Dark ice DOM contained significantly more aromatic (25 ± 3 %) and less biolabile (13 ± 4 %) DOM than weathering crust meltwater (3 ± 0 and 50 ± 0 %, respectively), pointing to retention of DOM on the ice surface and microbial, as well as photochemical alteration of DOM during transit through the supraglacial drainage system. These findings have implications for our understanding of supraglacial biogeochemical cycling, highlighting the importance of including the weathering crust photic zone when assessing supraglacial inputs to subglacial and downstream ecosystems. [ABSTRACT FROM AUTHOR]

Published

2024

2. Glacier algae accelerate melt rates on the south-western Greenland Ice Sheet.

Author

Cook, Joseph M., Tedstone, Andrew J., Williamson, Christopher, McCutcheon, Jenine, Hodson, Andrew J., Dayal, Archana, Skiles, McKenzie, Hofer, Stefan, Bryant, Robert, McAree, Owen, McGonigle, Andrew, Ryan, Jonathan, Anesio, Alexandre M., Irvine-Fynn, Tristram D. L., Hubbard, Alun, Hanna, Edward, Flanner, Mark, Mayanna, Sathish, Benning, Liane G., and van As, Dirk

Subjects

GREENLAND ice, ICE sheets, SNOWPACK augmentation, GLACIERS, ICE sheet thawing, ALGAL blooms, RADIATION absorption

Abstract

Melting of the Greenland Ice Sheet (GrIS) is the largest single contributor to eustatic sea level and is amplified by the growth of pigmented algae on the ice surface, which increases solar radiation absorption. This biological albedo-reducing effect and its impact upon sea level rise has not previously been quantified. Here, we combine field spectroscopy with a radiative-transfer model, supervised classification of unmanned aerial vehicle (UAV) and satellite remote-sensing data, and runoff modelling to calculate biologically driven ice surface ablation. We demonstrate that algal growth led to an additional 4.4–6.0 Gt of runoff from bare ice in the south-western sector of the GrIS in summer 2017, representing 10 %–13 % of the total. In localized patches with high biomass accumulation, algae accelerated melting by up to 26.15±3.77 % (standard error, SE). The year 2017 was a high-albedo year, so we also extended our analysis to the particularly low-albedo 2016 melt season. The runoff from the south-western bare-ice zone attributed to algae was much higher in 2016 at 8.8–12.2 Gt, although the proportion of the total runoff contributed by algae was similar at 9 %–13 %. Across a 10 000 km 2 area around our field site, algae covered similar proportions of the exposed bare ice zone in both years (57.99 % in 2016 and 58.89 % in 2017), but more of the algal ice was classed as "high biomass" in 2016 (8.35 %) than 2017 (2.54 %). This interannual comparison demonstrates a positive feedback where more widespread, higher-biomass algal blooms are expected to form in high-melt years where the winter snowpack retreats further and earlier, providing a larger area for bloom development and also enhancing the provision of nutrients and liquid water liberated from melting ice. Our analysis confirms the importance of this biological albedo feedback and that its omission from predictive models leads to the systematic underestimation of Greenland's future sea level contribution, especially because both the bare-ice zones available for algal colonization and the length of the biological growth season are set to expand in the future. [ABSTRACT FROM AUTHOR]

Published

2020

3. Dissolved organic nutrients dominate melting surface ice of the Dark Zone (Greenland Ice Sheet).

Author

Holland, Alexandra T., Williamson, Christopher J., Sgouridis, Fotis, Tedstone, Andrew J., McCutcheon, Jenine, Cook, Joseph M., Poniecka, Ewa, Yallop, Marian L., Tranter, Martyn, Anesio, Alexandre M., and The Black & Bloom Group

Subjects

MELTWATER, GREENLAND ice, ICE sheets, ICE, DISSOLVED organic matter, ALGAL blooms

Abstract

Glaciers and ice sheets host abundant and dynamic communities of microorganisms on the ice surface (supraglacial environments). Recently, it has been shown that Streptophyte glacier algae blooming on the surface ice of the south-western coast of the Greenland Ice Sheet are a significant contributor to the 15-year marked decrease in albedo. Currently, little is known about the constraints, such as nutrient availability, on this large-scale algal bloom. In this study, we investigate the relative abundances of dissolved inorganic and dissolved organic macronutrients (N and P) in these darkening surface ice environments. Three distinct ice surfaces, with low, medium and high visible impurity loadings, supraglacial stream water and cryoconite hole water, were sampled. Our results show a clear dominance of the organic phase in all ice surface samples containing low, medium and high visible impurity loadings, with 93 % of the total dissolved nitrogen and 67 % of the total dissolved phosphorus in the organic phase. Mean concentrations in low, medium and high visible impurity surface ice environments are 0.91, 0.62 and 1.0 µ M for dissolved inorganic nitrogen (DIN), 5.1, 11 and 14 µ M for dissolved organic nitrogen (DON), 0.03, 0.07 and 0.05 µ M for dissolved inorganic phosphorus (DIP) and 0.10, 0.15 and 0.12 µ M for dissolved organic phosphorus (DOP), respectively. DON concentrations in all three surface ice samples are significantly higher than DON concentrations in supraglacial streams and cryoconite hole water (0 and 0.7 µ M, respectively). DOP concentrations are higher in all three surface ice samples compared to supraglacial streams and cryoconite hole water (0.07 µ M for both). Dissolved organic carbon (DOC) concentrations increase with the amount of visible impurities present (low: 83 µ M, medium: 173 µ M and high: 242 µ M) and are elevated compared to supraglacial streams and cryoconite hole water (30 and 50 µ M, respectively). We speculate that the architecture of the weathering crust, which impacts on water flow paths and storage in the melting surface ice and/or the production of extracellular polymeric substances (EPS), containing both N and P in conjunction with C, is responsible for the temporary retention of DON and DOP in the melting surface ice. The unusual presence of measurable DIP and DIN, principally as NH4+ , in the melting surface ice environments suggests that factors other than macronutrient limitation are controlling the extent and magnitude of the glacier algae. [ABSTRACT FROM AUTHOR]

Published

2019

4. Nutrient cycling in supraglacial environments of the Dark Zone of the Greenland Ice Sheet.

Author

Holland, Alexandra T., Williamson, Christopher J., Sgouridis, Fotis, Tedstone, Andrew J., McCutcheon, Jenine, Cook, Joseph M., Poniecka, Ewa, Yallop, Marian L., Tranter, Martyn, and Anesio, Alexandre M.

Subjects

GREENLAND ice, ICE sheets, NUTRIENT cycles, ALGAL blooms, GLACIERS

Abstract

Glaciers and ice sheets host abundant and dynamic communities of microorganisms on the ice surface (supraglacial environments). Recently, it has been shown that Streptophyte ice algae blooming on the surface ice of the south-west coast of the Greenland Ice Sheet are a significant contributor to the 15-year marked decrease in albedo. Currently little is known about the constraints, such as the nutrient cycling, on this large-scale algal bloom. In this study, we present a preliminary data set that investigates the conversion of dissolved inorganic nutrients to the dissolved organic phase occurring in these darkening surface ice environments. Our results show a clear dominance of the organic phase, with 93% of the total dissolved nitrogen and 67% of the total dissolved phosphorus in the organic phase. Correlations between algal abundance and dissolved organic carbon and nitrogen, indicate ice algae are driving the dissolved nutrient phase shift occurring in these supraglacial environments. Dissolved organic nutrient ratios in these supraglacial environments are notably higher than the Redfield Ratio (DON:DOP=49, 78, 116) and DOC:DOP=797, 1166, 2013), suggesting these environments may be phosphorus limited. [ABSTRACT FROM AUTHOR]

Published

2019

5. Soil nitrogen response to shrub encroachment in a degrading semi-arid grassland.

Author

Turpin-Jelfs, Thomas, Michaelides, Katerina, Biederman, Joel A., and Anesio, Alexandre M.

Subjects

NITROGEN, SALTWATER encroachment, ARID regions biodiversity, SPATIAL distribution (Quantum optics), MESQUITE

Abstract

Transitions from grass- to shrub-dominated states in drylands by woody plant encroachment represent significant forms of land cover change with the potential to alter the spatial distribution and cycling of soil resources. Yet an understanding of how this phenomenon impacts the soil nitrogen pool, which is essential to primary production in arid and semi-arid systems, is poorly resolved. In this study, we quantified how the distribution and speciation of soil nitrogen, as well as rates of free-living biological nitrogen fixation, changed along a gradient of increasing mesquite (Prosopis velutina Woot.) cover in a semi-arid grassland of the southwestern US. Our results show that site-level concentrations of total nitrogen remain unchanged with increasing shrub cover as losses from inter-shrub areas (sum of grass and bare-soil cover) are proportional to increases in soils under shrub canopies. However, despite the similar carbon-to-nitrogen ratio and microbial biomass of soil from inter-shrub and shrub areas at each site, site-level concentrations of inorganic nitrogen increase with shrub cover due to the accumulation of ammonium and nitrate in soils beneath shrub canopies. Using the acetylene reduction assay technique, we found increasing ratios of inorganic nitrogen to bioavailable phosphorus inhibit rates of biological nitrogen fixation by free-living soil bacteria. Overall, these results provide a greater insight into how grassland-to-shrubland transitions influence the soil N pool through associated impacts on the soil microbial biomass. [ABSTRACT FROM AUTHOR]

Published

2019

6. Soil nitrogen response to shrub encroachment in a degrading semiarid grassland.

Author

Turpin-Jelfs, Thomas, Michaelides, Katerina, Biederman, Joel A., and Anesio, Alexandre M.

Subjects

WOODY plants, ARID regions, NITROGEN, MESQUITE, PLANT canopies

Abstract

Transitions from grass- to shrub-dominated states in drylands by woody plant encroachment represent significant forms of land cover change with the potential to alter the spatial distribution and cycling of soil resources. Yet an understanding of how this phenomenon impacts the soil nitrogen pool, which is essential to primary production in arid and semiarid systems, is poorly resolved. In this study, we quantified how the distribution and speciation of soil nitrogen, as well as rates of free-living biological nitrogen fixation, changed along a gradient of increasing mesquite (Prosopis velutina Woot.) cover in a semiarid grassland of the Southwestern US. Our results show that site-level concentrations of total nitrogen remain unchanged with increasing shrub cover as losses from intershrub areas (sum of grass and bare-soil cover) are proportional to increases in soils under shrub canopies. However, despite the similar carbon-to-nitrogen ratio and microbial biomass of soil from intershrub and shrub areas at each site, site-level concentrations of inorganic nitrogen increase with shrub cover due to the accumulation of ammonium and nitrate in soils beneath shrub canopies. Using the acetylene reduction assay technique, we found increasing ratios of inorganic nitrogen-to-bioavailable phosphorus inhibit rates of biological nitrogen fixation by free-living soil bacteria. Consequently, we conclude that shrub encroachment has the potential to significantly alter the dynamics of soil nitrogen cycling in dryland systems. [ABSTRACT FROM AUTHOR]

Published

2018