Widespread deoxygenation of temperate lakes

Stephen F. Jane; Gretchen J. A. Hansen; Benjamin M. Kraemer; Peter R. Leavitt; Joshua L. Mincer; Rebecca L. North; Rachel M. Pilla; Jonathan T. Stetler; Craig E. Williamson; R. Iestyn Woolway; Lauri Arvola; Sudeep Chandra; Curtis L. DeGasperi; Laura Diemer; Julita Dunalska; Oxana Erina; Giovanna Flaim; Hans-Peter Grossart; K. David Hambright; Catherine Hein; Josef Hejzlar; Lorraine L. Janus; Jean-Philippe Jenny; Lesley B. Knoll; Barbara Leoni; Eleanor Mackay; Shin-Ichiro S. Matsuzaki; Chris McBride; Dorthe C. Muller-Navarra; Andrew M. Paterson; Don Pierson; Michela Rogora; James A. Rusak; Steven Sadro; Emilie Saulnier-Talbot; Martin Schmid; Ruben Sommaruga; Wim Thiery; Piet Verburg; Kathleen C. Weathers; Gesa A. Weyhenmeyer; Kiyoko Yokota; Kevin C. Rose

doi:10.1038/s41586-021-03550-y

Widespread deoxygenation of temperate lakes

Stephen F. Jane
, Gretchen J. A. Hansen
, Benjamin M. Kraemer
, Peter R. Leavitt
, Joshua L. Mincer
, Rebecca L. North
, Rachel M. Pilla
, Jonathan T. Stetler
, Craig E. Williamson
, R. Iestyn Woolway
, Lauri Arvola
, Sudeep Chandra
, Curtis L. DeGasperi
, Laura Diemer
, Julita Dunalska
, Oxana Erina
, Giovanna Flaim
, Hans-Peter Grossart
, K. David Hambright
, Catherine Hein

Josef Hejzlar, Lorraine L. Janus, Jean-Philippe Jenny, Lesley B. Knoll, Barbara Leoni, Eleanor Mackay, Shin-Ichiro S. Matsuzaki, Chris McBride, Dorthe C. Muller-Navarra, Andrew M. Paterson, Don Pierson, Michela Rogora, James A. Rusak, Steven Sadro, Emilie Saulnier-Talbot, Martin Schmid, Ruben Sommaruga, Wim Thiery, Piet Verburg, Kathleen C. Weathers, Gesa A. Weyhenmeyer, Kiyoko Yokota, Kevin C. Rose

Ysgol Gwyddorau Eigion

Rensselaer Polytechnic Institute
University of Minnesota, USA
IGB Leibniz Institute for Freshwater Ecology and Inland Fisheries
University of Regina, Saskatchewan
University of Missouri, USA
University of Miami
University of Helsinki
University of Nevada
King County Water and Land Resources Division, Seattle
FB Environmental Associates, Portsmouth, NH, USA
University of Warmia and Mazury in Olsztyn
Lomonosov Moscow State University
Fondazione Edmund Mach, San Michele all’Adige, Italy
Leibniz-Institute of Freshwater Ecology and Inland Fisheries, Stechlin, Germany
The University of Oklahoma
Wisconsin Department of Natural Resources, Madison
Biology Centre CAS, České Budějovice
New York City Department of Environmental Protection
Université Savoie Mont Blanc
University of Milano Bicocca
Centre for Ecology & Hydrology, Lancaster
National Institute for Environmental Studies, Ibaraki, Japan
Environmental Research Institute, Hamilton, New Zealand
University of Hamburg
Ontario Ministry of the Environment Conservation and Parks
Uppsala University
CNR Water Research Institute (IRSA), Verbania Pallanza, Italy
University of California, Davis
Universite Laval
Swiss Federal Institute of Aquatic Science and Technology
University of Innsbruck
Vrije Universiteit Brussels
National Institute of Water and Atmospheric Research Ltd (NIWA), Hillcrest, Hamilton, New Zealand
Cary Institute of Ecosystem Studies, Millbrook, New York, USA
State University of New York College
Dundalk Institute of Technology

Allbwn ymchwil: Cyfraniad at gyfnodolyn › Erthygl › adolygiad gan gymheiriaid

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The concentration of dissolved oxygen in aquatic systems helps to regulate biodiversity1,2, nutrient biogeochemistry3, greenhouse gas emissions4, and the quality of drinking water5. The long-term declines in dissolved oxygen concentrations in coastal and ocean waters have been linked to climate warming and human activity6,7, but little is known about the changes in dissolved oxygen concentrations in lakes. Although the solubility of dissolved oxygen decreases with increasing water temperatures, long-term lake trajectories are difficult to predict. Oxygen losses in warming lakes may be amplified by enhanced decomposition and stronger thermal stratification8,9 or oxygen may increase as a result of enhanced primary production10. Here we analyse a combined total of 45,148 dissolved oxygen and temperature profiles and calculate trends for 393 temperate lakes that span 1941 to 2017. We find that a decline in dissolved oxygen is widespread in surface and deep-water habitats. The decline in surface waters is primarily associated with reduced solubility under warmer water temperatures, although dissolved oxygen in surface waters increased in a subset of highly productive warming lakes, probably owing to increasing production of phytoplankton. By contrast, the decline in deep waters is associated with stronger thermal stratification and loss of water clarity, but not with changes in gas solubility. Our results suggest that climate change and declining water clarity have altered the physical and chemical environment of lakes. Declines in dissolved oxygen in freshwater are 2.75 to 9.3 times greater than observed in the world’s oceans6,7 and could threaten essential lake ecosystem services

Iaith wreiddiol	Saesneg
Tudalennau (o-i)	66-70
Cyfnodolyn	Nature
Cyfrol	594
Rhif cyhoeddi	7861
Dynodwyr Gwrthrych Digidol (DOIs)	https://doi.org/10.1038/s41586-021-03550-y
Statws	Cyhoeddwyd - 2 Meh 2021

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10.1038/s41586-021-03550-y

Dyfynnu hyn

Jane, S. F., Hansen, G. J. A., Kraemer, B. M., Leavitt, P. R., Mincer, J. L., North, R. L., Pilla, R. M., Stetler, J. T., Williamson, C. E., Woolway, R. I., Arvola, L., Chandra, S., DeGasperi, C. L., Diemer, L., Dunalska, J., Erina, O., Flaim, G., Grossart, H.-P., Hambright, K. D., ... Rose, K. C. (2021). Widespread deoxygenation of temperate lakes. Nature, 594(7861), 66-70. https://doi.org/10.1038/s41586-021-03550-y

@article{3323bf12f04646e19d783bc9b9ec4163,

title = "Widespread deoxygenation of temperate lakes",

abstract = "The concentration of dissolved oxygen in aquatic systems helps to regulate biodiversity1,2, nutrient biogeochemistry3, greenhouse gas emissions4, and the quality of drinking water5. The long-term declines in dissolved oxygen concentrations in coastal and ocean waters have been linked to climate warming and human activity6,7, but little is known about the changes in dissolved oxygen concentrations in lakes. Although the solubility of dissolved oxygen decreases with increasing water temperatures, long-term lake trajectories are difficult to predict. Oxygen losses in warming lakes may be amplified by enhanced decomposition and stronger thermal stratification8,9 or oxygen may increase as a result of enhanced primary production10. Here we analyse a combined total of 45,148 dissolved oxygen and temperature profiles and calculate trends for 393 temperate lakes that span 1941 to 2017. We find that a decline in dissolved oxygen is widespread in surface and deep-water habitats. The decline in surface waters is primarily associated with reduced solubility under warmer water temperatures, although dissolved oxygen in surface waters increased in a subset of highly productive warming lakes, probably owing to increasing production of phytoplankton. By contrast, the decline in deep waters is associated with stronger thermal stratification and loss of water clarity, but not with changes in gas solubility. Our results suggest that climate change and declining water clarity have altered the physical and chemical environment of lakes. Declines in dissolved oxygen in freshwater are 2.75 to 9.3 times greater than observed in the world{\textquoteright}s oceans6,7 and could threaten essential lake ecosystem services",

author = "Jane, \{Stephen F.\} and Hansen, \{Gretchen J. A.\} and Kraemer, \{Benjamin M.\} and Leavitt, \{Peter R.\} and Mincer, \{Joshua L.\} and North, \{Rebecca L.\} and Pilla, \{Rachel M.\} and Stetler, \{Jonathan T.\} and Williamson, \{Craig E.\} and Woolway, \{R. Iestyn\} and Lauri Arvola and Sudeep Chandra and DeGasperi, \{Curtis L.\} and Laura Diemer and Julita Dunalska and Oxana Erina and Giovanna Flaim and Hans-Peter Grossart and Hambright, \{K. David\} and Catherine Hein and Josef Hejzlar and Janus, \{Lorraine L.\} and Jean-Philippe Jenny and Knoll, \{Lesley B.\} and Barbara Leoni and Eleanor Mackay and Matsuzaki, \{Shin-Ichiro S.\} and Chris McBride and Muller-Navarra, \{Dorthe C.\} and Paterson, \{Andrew M.\} and Don Pierson and Michela Rogora and Rusak, \{James A.\} and Steven Sadro and Emilie Saulnier-Talbot and Martin Schmid and Ruben Sommaruga and Wim Thiery and Piet Verburg and Weathers, \{Kathleen C.\} and Weyhenmeyer, \{Gesa A.\} and Kiyoko Yokota and Rose, \{Kevin C.\}",

year = "2021",

month = jun,

day = "2",

doi = "10.1038/s41586-021-03550-y",

language = "English",

volume = "594",

pages = "66--70",

journal = "Nature",

issn = "0028-0836",

publisher = "Nature Research",

number = "7861",

}

Jane, SF, Hansen, GJA, Kraemer, BM, Leavitt, PR, Mincer, JL, North, RL, Pilla, RM, Stetler, JT, Williamson, CE, Woolway, RI, Arvola, L, Chandra, S, DeGasperi, CL, Diemer, L, Dunalska, J, Erina, O, Flaim, G, Grossart, H-P, Hambright, KD, Hein, C, Hejzlar, J, Janus, LL, Jenny, J-P, Knoll, LB, Leoni, B, Mackay, E, Matsuzaki, S-IS, McBride, C, Muller-Navarra, DC, Paterson, AM, Pierson, D, Rogora, M, Rusak, JA, Sadro, S, Saulnier-Talbot, E, Schmid, M, Sommaruga, R, Thiery, W, Verburg, P, Weathers, KC, Weyhenmeyer, GA, Yokota, K & Rose, KC 2021, 'Widespread deoxygenation of temperate lakes', Nature, cyfrol. 594, rhif 7861, tt. 66-70. https://doi.org/10.1038/s41586-021-03550-y

TY - JOUR

T1 - Widespread deoxygenation of temperate lakes

AU - Jane, Stephen F.

AU - Hansen, Gretchen J. A.

AU - Kraemer, Benjamin M.

AU - Leavitt, Peter R.

AU - Mincer, Joshua L.

AU - North, Rebecca L.

AU - Pilla, Rachel M.

AU - Stetler, Jonathan T.

AU - Williamson, Craig E.

AU - Woolway, R. Iestyn

AU - Arvola, Lauri

AU - Chandra, Sudeep

AU - DeGasperi, Curtis L.

AU - Diemer, Laura

AU - Dunalska, Julita

AU - Erina, Oxana

AU - Flaim, Giovanna

AU - Grossart, Hans-Peter

AU - Hambright, K. David

AU - Hein, Catherine

AU - Hejzlar, Josef

AU - Janus, Lorraine L.

AU - Jenny, Jean-Philippe

AU - Knoll, Lesley B.

AU - Leoni, Barbara

AU - Mackay, Eleanor

AU - Matsuzaki, Shin-Ichiro S.

AU - McBride, Chris

AU - Muller-Navarra, Dorthe C.

AU - Paterson, Andrew M.

AU - Pierson, Don

AU - Rogora, Michela

AU - Rusak, James A.

AU - Sadro, Steven

AU - Saulnier-Talbot, Emilie

AU - Schmid, Martin

AU - Sommaruga, Ruben

AU - Thiery, Wim

AU - Verburg, Piet

AU - Weathers, Kathleen C.

AU - Weyhenmeyer, Gesa A.

AU - Yokota, Kiyoko

AU - Rose, Kevin C.

PY - 2021/6/2

Y1 - 2021/6/2

N2 - The concentration of dissolved oxygen in aquatic systems helps to regulate biodiversity1,2, nutrient biogeochemistry3, greenhouse gas emissions4, and the quality of drinking water5. The long-term declines in dissolved oxygen concentrations in coastal and ocean waters have been linked to climate warming and human activity6,7, but little is known about the changes in dissolved oxygen concentrations in lakes. Although the solubility of dissolved oxygen decreases with increasing water temperatures, long-term lake trajectories are difficult to predict. Oxygen losses in warming lakes may be amplified by enhanced decomposition and stronger thermal stratification8,9 or oxygen may increase as a result of enhanced primary production10. Here we analyse a combined total of 45,148 dissolved oxygen and temperature profiles and calculate trends for 393 temperate lakes that span 1941 to 2017. We find that a decline in dissolved oxygen is widespread in surface and deep-water habitats. The decline in surface waters is primarily associated with reduced solubility under warmer water temperatures, although dissolved oxygen in surface waters increased in a subset of highly productive warming lakes, probably owing to increasing production of phytoplankton. By contrast, the decline in deep waters is associated with stronger thermal stratification and loss of water clarity, but not with changes in gas solubility. Our results suggest that climate change and declining water clarity have altered the physical and chemical environment of lakes. Declines in dissolved oxygen in freshwater are 2.75 to 9.3 times greater than observed in the world’s oceans6,7 and could threaten essential lake ecosystem services

AB - The concentration of dissolved oxygen in aquatic systems helps to regulate biodiversity1,2, nutrient biogeochemistry3, greenhouse gas emissions4, and the quality of drinking water5. The long-term declines in dissolved oxygen concentrations in coastal and ocean waters have been linked to climate warming and human activity6,7, but little is known about the changes in dissolved oxygen concentrations in lakes. Although the solubility of dissolved oxygen decreases with increasing water temperatures, long-term lake trajectories are difficult to predict. Oxygen losses in warming lakes may be amplified by enhanced decomposition and stronger thermal stratification8,9 or oxygen may increase as a result of enhanced primary production10. Here we analyse a combined total of 45,148 dissolved oxygen and temperature profiles and calculate trends for 393 temperate lakes that span 1941 to 2017. We find that a decline in dissolved oxygen is widespread in surface and deep-water habitats. The decline in surface waters is primarily associated with reduced solubility under warmer water temperatures, although dissolved oxygen in surface waters increased in a subset of highly productive warming lakes, probably owing to increasing production of phytoplankton. By contrast, the decline in deep waters is associated with stronger thermal stratification and loss of water clarity, but not with changes in gas solubility. Our results suggest that climate change and declining water clarity have altered the physical and chemical environment of lakes. Declines in dissolved oxygen in freshwater are 2.75 to 9.3 times greater than observed in the world’s oceans6,7 and could threaten essential lake ecosystem services

U2 - 10.1038/s41586-021-03550-y

DO - 10.1038/s41586-021-03550-y

M3 - Article

SN - 0028-0836

VL - 594

SP - 66

EP - 70

JO - Nature

JF - Nature

IS - 7861

ER -

Widespread deoxygenation of temperate lakes

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