Terrestrial carbon inputs to inland waters: A current synthesis of estimates and uncertainty

Globally, inland waters receive a significant but ill‐defined quantity of terrestrial carbon (C). When summed, the contemporary estimates for the three possible fates of C in inland waters (storage, outgassing, and export) highlight that terrestrial landscapes may deliver upward of 5.1 Pg of C annua...

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Vydáno v:Limnology and oceanography letters Ročník 3; číslo 3; s. 132 - 142
Hlavní autoři: Drake, Travis W., Raymond, Peter A., Spencer, Robert G. M.
Médium: Journal Article
Jazyk:angličtina
Vydáno: Hoboken John Wiley & Sons, Inc 01.06.2018
Wiley
Témata:
Aquatic ecosystems
Atmosphere
Carbon dioxide
Estimates
Oceans
open climate campaign
Respiration
Terrestrial ecosystems
Terrestrial environments
Tropical environments
Waterways
ISSN:2378-2242, 2378-2242
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Abstract Globally, inland waters receive a significant but ill‐defined quantity of terrestrial carbon (C). When summed, the contemporary estimates for the three possible fates of C in inland waters (storage, outgassing, and export) highlight that terrestrial landscapes may deliver upward of 5.1 Pg of C annually. This review of flux estimates over the last decade has revealed an average increase of ∼ 0.3 Pg C yr−1, indicating a historical underestimation of the amount of terrestrial‐C exported to inland waters. The continual increase in the estimates also underscores large data gaps and uncertainty. As research continues to refine these aquatic fluxes, especially C outgassed from the humid tropics and other understudied regions, we expect the global estimate of terrestrial‐C transferred to inland waters to rise. An important implication of this upward refinement is that terrestrial net ecosystem production may be overestimated with ramifications for modeling of the global C cycle.
AbstractList Globally, inland waters receive a significant but ill‐defined quantity of terrestrial carbon (C). When summed, the contemporary estimates for the three possible fates of C in inland waters (storage, outgassing, and export) highlight that terrestrial landscapes may deliver upward of 5.1 Pg of C annually. This review of flux estimates over the last decade has revealed an average increase of ∼ 0.3 Pg C yr−1, indicating a historical underestimation of the amount of terrestrial‐C exported to inland waters. The continual increase in the estimates also underscores large data gaps and uncertainty. As research continues to refine these aquatic fluxes, especially C outgassed from the humid tropics and other understudied regions, we expect the global estimate of terrestrial‐C transferred to inland waters to rise. An important implication of this upward refinement is that terrestrial net ecosystem production may be overestimated with ramifications for modeling of the global C cycle.
Abstract Globally, inland waters receive a significant but ill‐defined quantity of terrestrial carbon (C). When summed, the contemporary estimates for the three possible fates of C in inland waters (storage, outgassing, and export) highlight that terrestrial landscapes may deliver upward of 5.1 Pg of C annually. This review of flux estimates over the last decade has revealed an average increase of ∼ 0.3 Pg C yr−1, indicating a historical underestimation of the amount of terrestrial‐C exported to inland waters. The continual increase in the estimates also underscores large data gaps and uncertainty. As research continues to refine these aquatic fluxes, especially C outgassed from the humid tropics and other understudied regions, we expect the global estimate of terrestrial‐C transferred to inland waters to rise. An important implication of this upward refinement is that terrestrial net ecosystem production may be overestimated with ramifications for modeling of the global C cycle.
Globally, inland waters receive a significant but ill‐defined quantity of terrestrial carbon (C). When summed, the contemporary estimates for the three possible fates of C in inland waters (storage, outgassing, and export) highlight that terrestrial landscapes may deliver upward of 5.1 Pg of C annually. This review of flux estimates over the last decade has revealed an average increase of ∼ 0.3 Pg C yr −1 , indicating a historical underestimation of the amount of terrestrial‐C exported to inland waters. The continual increase in the estimates also underscores large data gaps and uncertainty. As research continues to refine these aquatic fluxes, especially C outgassed from the humid tropics and other understudied regions, we expect the global estimate of terrestrial‐C transferred to inland waters to rise. An important implication of this upward refinement is that terrestrial net ecosystem production may be overestimated with ramifications for modeling of the global C cycle.
Author Raymond, Peter A.
Spencer, Robert G. M.
Drake, Travis W.
Author_xml – sequence: 1
  givenname: Travis W.
  orcidid: 0000-0002-7564-974X
  surname: Drake
  fullname: Drake, Travis W.
  email: draketw@gmail.com
  organization: Florida State University
– sequence: 2
  givenname: Peter A.
  orcidid: 0000-0002-8564-7860
  surname: Raymond
  fullname: Raymond, Peter A.
  organization: Yale University
– sequence: 3
  givenname: Robert G. M.
  orcidid: 0000-0003-0777-0748
  surname: Spencer
  fullname: Spencer, Robert G. M.
  organization: Florida State University
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Copyright 2017 The Author. Limnology and Oceanography Letters published by Wiley Periodicals, Inc. on behalf of Association for the Sciences of Limnology and Oceanography
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Notes Edited by: Emily Stanley and Paul del Giorgio
Data Availability Statement
TWD and RGMS conceived the manuscript. TWD generated new estimates and wrote the manuscript with significant contributions from PAR and RGMS.
This article is part of the Special Issue: Carbon cycling in inland waters
Author Contribution Statement
All data in the manuscript can be found in cited publications and in Table
.
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SSID ssj0001617538
Score 2.5707846
Snippet Globally, inland waters receive a significant but ill‐defined quantity of terrestrial carbon (C). When summed, the contemporary estimates for the three...
Abstract Globally, inland waters receive a significant but ill‐defined quantity of terrestrial carbon (C). When summed, the contemporary estimates for the...
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SubjectTerms Aquatic ecosystems
Atmosphere
Carbon dioxide
Estimates
Oceans
open climate campaign
Respiration
Terrestrial ecosystems
Terrestrial environments
Tropical environments
Waterways
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Title Terrestrial carbon inputs to inland waters: A current synthesis of estimates and uncertainty
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