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07 02, 2019;53 (13): 7203-7214.

Non-floodplain Wetlands Affect Watershed Nutrient Dynamics: A Critical Review.

Heather E Golden, Adnan Rajib, Charles R Lane, Jay R Christensen, Qiusheng Wu, Samson Mengistu
Author Information
  1. Heather E Golden: National Exposure Research Laboratory , U.S. Environmental Protection Agency , Office of Research and Development, 26 West Martin Luther King Drive , Cincinnati , Ohio 45268 , United States. ORCID
  2. Adnan Rajib: Oak Ridge Institute for Science and Education , c/o Environmental Protection Agency, Office of Research and Development, 26 West Martin Luther King Drive , Cincinnati , Ohio 45268 , United States.
  3. Charles R Lane: National Exposure Research Laboratory , U.S. Environmental Protection Agency , Office of Research and Development, 26 West Martin Luther King Drive , Cincinnati , Ohio 45268 , United States. ORCID
  4. Jay R Christensen: National Exposure Research Laboratory , U.S. Environmental Protection Agency , Office of Research and Development, 26 West Martin Luther King Drive , Cincinnati , Ohio 45268 , United States.
  5. Qiusheng Wu: Department of Geography , University of Tennessee , Knoxville , Tennessee 37996 , United States. ORCID
  6. Samson Mengistu: National Research Council , National Academy of Sciences, c/o Environmental Protection Agency, Office of Research and Development, 26 West Martin Luther King Drive , Cincinnati , Ohio 45268 , United States.
PMID: 31244063 DOI: 10.1021/acs.est.8b07270

Abstract

Wetlands have the capacity to retain nitrogen and phosphorus and are thereby often considered a viable option for improving water quality at local scales. However, little is known about the cumulative influence of wetlands outside of floodplains, i.e., non-floodplain wetlands (NFWs), on surface water quality at watershed scales. Such evidence is important to meet global, national, regional, and local water quality goals effectively and comprehensively. In this critical review, we synthesize the state of the science about the watershed-scale effects of NFWs on nutrient-based (nitrogen, phosphorus) water quality. We further highlight where knowledge is limited in this research area and the challenges of garnering this information. On the basis of previous wetland literature, we develop emerging concepts that assist in advancing the science linking NFWs to watershed-scale nutrient conditions. Finally, we ask, "Where do we go from here?" We address this question using a 2-fold approach. First, we demonstrate, via example model simulations, how explicitly considering NFWs in watershed nutrient modeling changes predicted nutrient yields to receiving waters-and how this may potentially affect future water quality management decisions. Second, we outline research recommendations that will improve our scientific understanding of how NFWs affect downstream water quality.

References

  1. Nat Geosci. 2017;10(11):809-815 [PMID: 30079098]
  2. Trends Ecol Evol. 2006 Feb;21(2):96-103 [PMID: 16701481]
  3. Ecol Appl. 2015 Mar;25(2):451-65 [PMID: 26263667]
  4. Environ Sci Technol. 2018 May 15;52(10):5519-5529 [PMID: 29656639]
  5. Int J Remote Sens. 2019 May 1;40(15):5768-5798 [PMID: 33408426]
  6. Front Ecol Environ. 2017 Aug;15(6):319-327 [PMID: 30505246]
  7. Environ Manage. 2013 Feb;51(2):392-413 [PMID: 23180248]
  8. WIREs Water. 2018;5(1):1254 [PMID: 29682288]
  9. Environ Sci Pollut Res Int. 2003;10(2):126-39 [PMID: 12729046]
  10. Hydrol Process. 2018;32(2):305-313 [PMID: 29681686]
  11. J Am Water Resour Assoc. 2018;54(2):298-322 [PMID: 30078985]
  12. Ecol Appl. 2018 Jun;28(4):953-966 [PMID: 29437239]
  13. Environ Manage. 1996 Sep;20(5):731-9 [PMID: 8703110]
  14. J Am Water Resour Assoc. 2018 Mar 1;54:346-371 [PMID: 34887654]
  15. Environ Model Softw. 2018 Nov;109:368-379 [PMID: 30505208]
  16. Ambio. 2005 Nov;34(7):544-51 [PMID: 16435744]
  17. Science. 1985 Jun 21;228(4706):1424-7 [PMID: 17814487]
  18. Proc Natl Acad Sci U S A. 2008 Aug 12;105(32):11254-8 [PMID: 18667696]
  19. Environ Sci Technol. 2007 Aug 1;41(15):5410-8 [PMID: 17822110]
  20. J Am Water Resour Assoc. 2019 Apr 5;55(2):354-368 [PMID: 33776405]
  21. J Environ Qual. 2018 Jul;47(4):902-913 [PMID: 30025042]
  22. Sci Total Environ. 2014 Jan 15;468-469:1255-66 [PMID: 24060142]
  23. J Environ Qual. 2012 May-Jun;41(3):621-7 [PMID: 22565243]
  24. J Am Water Resour Assoc. 2019 May 1;55(3):559-577 [PMID: 34316250]
  25. J Hydrol Eng. 2017;22(1):1-18 [PMID: 30713418]
  26. J Environ Manage. 2017 May 1;192:184-196 [PMID: 28160646]
  27. J Hydrol (Amst). 2018;567:668-683 [PMID: 31395990]
  28. Environ Sci Technol. 2012 Aug 21;46(16):9174-82 [PMID: 22827327]
  29. Water Sci Technol. 2001;44(11-12):559-64 [PMID: 11804150]
  30. Water Resour Res. 2018 Mar 09;54(2):995-977 [PMID: 29681665]
  31. J Environ Manage. 2010 Jul;91(7):1511-25 [PMID: 20236754]
  32. J Environ Qual. 2011 Mar-Apr;40(2):620-33 [PMID: 21520769]
  33. J Environ Qual. 2003 Jul-Aug;32(4):1534-47 [PMID: 12931911]
  34. Proc Natl Acad Sci U S A. 2016 Feb 23;113(8):1978-86 [PMID: 26858425]
  35. Science. 2008 Aug 15;321(5891):926-9 [PMID: 18703733]
  36. J Environ Manage. 2018 Oct 1;223:37-48 [PMID: 29886149]
  37. Hydrol Process. 2018 Feb 15;32(4):516-532 [PMID: 29576682]

Grants

  1. EPA999999/Intramural EPA

MeSH Term

Nitrogen
Nutrients
Phosphorus
Water Quality
Wetlands

Chemicals

Phosphorus
Nitrogen
Journal Article Review
Article has an altmetric score of 9

Word Cloud

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