Your search keyword '"Battin, Tom I."' showing total 6 results

1. Half of global methane emissions come from highly variable aquatic ecosystem sources

Author

Rosentreter, Judith A., Borges, Alberto V., Deemer, Bridget R., Holgerson, Meredith A., Liu, Shaoda, Song, Chunlin, Melack, John, Raymond, Peter A., Duarte, Carlos M., Allen, George H., Olefeldt, David, Poulter, Benjamin, Battin, Tom I., and Eyre, Bradley D.

Published

2021

2. Gradients of Deposition and In Situ Production Drive Global Glacier Organic Matter Composition.

Author

Holt, Amy D., McKenna, Amy M., Kellerman, Anne M., Battin, Tom I., Fellman, Jason B., Hood, Eran, Peter, Hannes, Schön, Martina, De Staercke, Vincent, Styllas, Michail, Tolosano, Matteo, and Spencer, Robert G. M.

Subjects

DISSOLVED organic matter, ATMOSPHERIC deposition, GLACIAL melting, CARBON cycle, CARBON isotopes

Abstract

Runoff from rapidly melting mountain glaciers is a dominant source of riverine organic carbon in many high‐latitude and high‐elevation regions. Glacier dissolved organic carbon is highly bioavailable, and its composition likely reflects internal (e.g., autotrophic production) and external (i.e., atmospheric deposition) sources. However, the balance of these sources across Earth's glaciers is poorly understood, despite implications for the mineralization and assimilation of glacier organic carbon within recipient ecosystems. We assessed the molecular‐level composition of dissolved organic matter from 136 mountain glacier outflows from 11 regions covering six continents using ultrahigh resolution 21 T mass spectrometry. We found substantial diversity in organic matter composition with coherent and predictable (80% accuracy) regional patterns. Employing stable and radiocarbon isotopic analyses, we demonstrate that these patterns are inherently linked to atmospheric deposition and in situ production. In remote regions like Greenland and New Zealand, the glacier organic matter pool appears to be dominated by in situ production. However, downwind of industrial centers (e.g., Alaska and Nepal), fossil fuel combustion byproducts likely underpin organic matter composition, resulting in older and more aromatic material being exported downstream. These findings highlight that the glacier carbon cycle is spatially distinct, with ramifications for predicting the dynamics and fate of glacier organic carbon concurrent with continued retreat and anthropogenic perturbation. Plain Language Summary: The controls on glacier organic matter composition globally remain poorly constrained, despite the importance of this material for downstream carbon cycling, and freshwater and marine ecosystems. We present the first systematic global analysis of glacier dissolved organic matter and demonstrate that its composition is largely determined by the relative balance of organic material derived from in situ production versus atmospheric deposition. As a result, globally, glaciers can be considered a diverse organic matter pool, exporting regionally distinct material to recipient ecosystems. Glaciers relatively dominated by atmospheric‐derived organics export older and more stable material with ramifications for the fate of glacier‐derived carbon in recipient ecosystems. Ultimately, this work highlights glaciers globally as having a dynamic role in carbon cycling. Key Points: Glacier dissolved organic matter is diverse but with an underlying compositional uniformity suggesting universal controls on compositionComposition appears driven by the relative balance of in situ production versus atmospheric deposition derived organic matterGlacier dissolved organic matter composition is predictable by region and linked to source [ABSTRACT FROM AUTHOR]

Published

2024

3. Ecosystem engineering by periphyton in Alpine proglacial streams

Author

Roncoroni, Matteo, primary, Ballu, Aurélien, additional, Selitaj, Adrijan, additional, Mancini, Davide, additional, Miesen, Floreana, additional, Aguet, Marc, additional, Battin, Tom I., additional, and Lane, Stuart N., additional

Published

2023

4. Ecosystem engineering by periphyton in Alpine proglacial streams.

Author

Roncoroni, Matteo, Ballu, Aurélien, Selitaj, Adrijan, Mancini, Davide, Miesen, Floreana, Aguet, Marc, Battin, Tom I., and Lane, Stuart N.

Subjects

PERIPHYTON, ECOLOGICAL succession, GLACIAL drift, COLONIZATION (Ecology), ALLUVIAL plains, MOUNTAIN ecology, GLACIERS, MELTWATER

Abstract

Stream periphytons are candidate ecosystem engineers in proglacial margins. Here, we quantify the extent to which they are engineers for the case of hillslope‐fed tributaries in the terrace zones of proglacial margin alluvial plains. Candidate ecosystem engineering effects relate to periphyton‐driven changes in (1) vertical infiltration of water, which in turn could aid plant colonization and hence local surface stabilization, and (2) near‐bed hydraulics, notably near‐bed turbulence properties. We ran two flume experiments in parallel in the proglacial margin of the Otemma glacier (Switzerland), reproducing the environmental conditions found in terrace streams. In both experiments, we followed periphyton development on initially bare sediments for 28 days. Then, whilst the experiment continued undisturbed in one flume, in the second and over a further 26 days, we introduced disturbances in the form of desiccation events. Throughout the entire experiment length, we collected imagery for close‐range SfM‐MVS photogrammetry, data on vertical infiltration, and near‐bed hydraulics. The experiments showed that periphyton development significantly changed the streambed properties. First, periphyton development over the timescale of a few days reduced bed roughness and clogged the benthic interstitial space, reducing water infiltration. These effects were insensitive to the disturbance regime. Second, the changes in streambed roughness modified the near‐bed turbulent structures, and this resulted in a reduction of bursting events and in the modification of the turbulent kinetic energy at the near‐bed layer. The latter, however, appeared to be less important in these environments as compared with the impacts on infiltration. Given the low water retaining capacity of glacial sediments, the observation that periphyton can reduce vertical infiltration explains wider observations of their importance in glacial floodplains where vegetation succession is critically constrained by water availability. The relatively reduced impacts on near‐bed turbulence also contribute to explaining why disturbance in proglacial margin streams remains a key limit on ecological succession. [ABSTRACT FROM AUTHOR]

Published

2024

5. A tropical cocktail of organic matter sources: Variability in supraglacial and glacier outflow dissolved organic matter composition and age across the Ecuadorian Andes

Author

Holt, Amy D., primary, Kellerman, Anne M., additional, Battin, Tom. I, additional, McKenna, Amy M., additional, Hood, Eran, additional, Andino, Patricio, additional, Crespo‐Pérez, Verónica, additional, Peter, Hannes, additional, Schön, Martina, additional, De Staercke, Vincent, additional, Styllas, Michail, additional, Tolosano, Matteo, additional, and Spencer, Robert G.M., additional

Published

2023

6. Ecosystem engineers: Biofilms and the ontogeny of glacier floodplain ecosystems

Author

Roncoroni, Matteo, primary, Brandani, Jade, additional, Battin, Tom I., additional, and Lane, Stuart N., additional

Published

2019