Free Standard AU & NZ Shipping For All Book Orders Over $80!
Register      Login
Marine and Freshwater Research Marine and Freshwater Research Society
Advances in the aquatic sciences
RESEARCH ARTICLE

Sediment accretion and accumulation of P, N and organic C in depressional wetlands of three ecoregions of the United States

C. R. Lane A B and B. C. Autrey A
+ Author Affiliations
- Author Affiliations

A US Environmental Protection Agency, Office of Research and Development, National Exposure Research Laboratory, Cincinnati, OH 45268, USA.

B Corresponding author. Email: lane.charles@epa.gov

Marine and Freshwater Research 68(12) 2253-2265 https://doi.org/10.1071/MF16372
Submitted: 12 November 2016  Accepted: 6 April 2017   Published: 6 July 2017

Abstract

Wetland depressions without surface channel connections to aquatic systems are substantial sinks for nitrogen (N), phosphorus (P) and organic carbon (org. C). We assessed accretion, N, P and org.-C accumulation rates in 43 depressional wetlands across three ecoregions of the USA (Erie Drift Plain, EDP; Middle Atlantic Coastal Plain, MACP; Southern Coastal Plain, SCP) using caesium-137 (137Cs). The mean sediment accretion rate in minimally affected (reference) sites was 0.6 ± 0.4 mm year–1 and did not differ among ecoregions. Accumulation rates for N and org. C averaged 3.1 ± 3.1 g N m–2 year–1 and 43.4 ± 39.0 g org. C m–2 year–1 respectively, and did not differ across minimally affected sites. Phosphorus accumulation rates were significantly greater in EDP (0.10 ± 0.10 g P m–2 year–1) than MACP (0.01 ± 0.01 g P m–2 year–1) or SCP (0.04 ± 0.04 g P m–2 year–1) sites. Land-use modality and wetland-type effects were analysed in SCP, with few differences being found. Depressional wetlands sequester substantive amounts of nutrients and C; their cumulative contributions may significantly affect landscape nutrient and C dynamics because of the abundance of wetland depressions on the landscape, warranting further investigation and potential watershed-scale conservation approaches.

Additional keywords: assimilation, caesium-137, ecosystem services, geographically isolated wetland, sequestration, upland embedded wetland


References

Alexander, L. C. (2015). Science at the boundaries: scientific support for the Clean Water Rule. Freshwater Science 34, 1588–1594.
Science at the boundaries: scientific support for the Clean Water Rule.Crossref | GoogleScholarGoogle Scholar |

Arango, C. P., and Tank, J. L. (2008). Land use influences the spatiotemporal controls on nitrification and denitrification in headwater streams. Journal of the North American Benthological Society 27, 90–107.
Land use influences the spatiotemporal controls on nitrification and denitrification in headwater streams.Crossref | GoogleScholarGoogle Scholar |

Badiou, P., McDougal, R., Pennock, D., and Clark, B. (2011). Greenhouse gas emissions and carbon sequestration potential in restored wetlands of the Canadian prairie pothole region. Wetlands Ecology and Management 19, 237–256.
Greenhouse gas emissions and carbon sequestration potential in restored wetlands of the Canadian prairie pothole region.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BC3MXnsVCmu7s%3D&md5=6306768c3e0f3ed0c56a3d2ba81bd7d6CAS |

Battle, J., and Golladay, S. (2007). How hydrology, habitat type, and litter quality affect leaf breakdown in wetlands on the Gulf Coastal Plain of Georgia. Wetlands 27, 251–260.
How hydrology, habitat type, and litter quality affect leaf breakdown in wetlands on the Gulf Coastal Plain of Georgia.Crossref | GoogleScholarGoogle Scholar |

Bernal, B., and Mitsch, W. J. (2012). Comparing carbon sequestration in temperate freshwater wetland communities. Global Change Biology 18, 1636–1647.
Comparing carbon sequestration in temperate freshwater wetland communities.Crossref | GoogleScholarGoogle Scholar |

Besasie, N. J., and Buckley, M. E. (2012). Carbon sequestration potential at central Wisconsin Wetland Reserve Program sites. Soil Science Society of America Journal 76, 1904–1910.
Carbon sequestration potential at central Wisconsin Wetland Reserve Program sites.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BC38XhsVOmsrrO&md5=c31395c0bcb627e158915b16f87dbf94CAS |

Bhadha, J. H., and Jawitz, J. W. (2010). Characterizing deep soils from an impacted subtropical isolated wetland: implications for phosphorus storage. Journal of Soils and Sediments 10, 514–525.
Characterizing deep soils from an impacted subtropical isolated wetland: implications for phosphorus storage.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BC3cXjs1Wqsbw%3D&md5=f1dccab090fb45597c079135dd10993dCAS |

Cabezas, A., Matthias, P., Schönfelder, I., Gelbrecht, J., and Zak, D. (2014). Carbon, nitrogen, and phosphorus accumulation in novel ecosystems: shallow lakes in degraded fen areas. Ecological Engineering 66, 63–71.
Carbon, nitrogen, and phosphorus accumulation in novel ecosystems: shallow lakes in degraded fen areas.Crossref | GoogleScholarGoogle Scholar |

Cheesman, A. W., Dunne, E. J., Turner, B. L., and Ramesh, R. K. (2010). Soil phosphorus forms in hydrologically isolated wetlands and surrounding pasture uplands. Journal of Environmental Quality 39, 1517–1525.
Soil phosphorus forms in hydrologically isolated wetlands and surrounding pasture uplands.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BC3cXoslKmur4%3D&md5=b308c584c600969e1e1fc03c1e33473dCAS |

Cohen, M. J., Dunne, E. J., and Bruland, G. L. (2008). Spatial variability of soil properties in cypress domes surrounded by different land uses. Wetlands 28, 411–422.
Spatial variability of soil properties in cypress domes surrounded by different land uses.Crossref | GoogleScholarGoogle Scholar |

Cohen, M. J., Creed, I. F., Alexander, L., Basu, N., Calhoun, A., Craft, C., D’Amico, E., DeKeyser, E., Fowler, L., Golden, H. E., Jawitz, J. W., Kalla, P., Kirkman, L. K., Lane, C. R., Lang, M. W., Leibowitz, S. G., Lewis, D. B., Marton, J., McLaughlin, D. L., Mushet, D., Raanan-Kipperwas, H., Rains, M. C., Smith, L., and Walls, S. (2016). Do geographically isolated wetlands influence landscape function? Proceedings of the National Academy of Sciences of the United States of America 113, 1978–1986.
Do geographically isolated wetlands influence landscape function?Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BC28Xit12rsrs%3D&md5=77a57281387f91700de1d4654bd8856bCAS |

Comer, P., Goodwin, K., Tomaino, A., Hammerson, G., Kittel, G., Menard, S., Nordman, C., Pyne, M., Reid, M., Sneddon, L., and Snow, K. (2005). ‘Biodiversity Values of Geographically Isolated Wetlands in the United States.’ (Natureserve: Arlington, VA, USA.)

Cowardin, L. M., Carter, V., Goulet, F. C., and LaRoe, E. T. (1979). ‘Classification of Wetlands and Deepwater Habitats of the United States.’(Fish and Wildlife Service: Washington DC., USA.)

Craft, C. B. (2012). Tidal freshwater forest accretion does not keep pace with sea level rise. Global Change Biology 18, 3615–3623.
Tidal freshwater forest accretion does not keep pace with sea level rise.Crossref | GoogleScholarGoogle Scholar |

Craft, C. B., and Casey, W. P. (2000). Sediment and nutrient accumulation in floodplain and depressional freshwater wetlands of Georgia, USA. Wetlands 20, 323–332.
Sediment and nutrient accumulation in floodplain and depressional freshwater wetlands of Georgia, USA.Crossref | GoogleScholarGoogle Scholar |

Craft, C. B., and Chiang, C. (2002). Forms and amounts of soil nitrogen and phosphorus across a longleaf pine-depressional wetland landscape. Soil Science Society of America Journal 66, 1713–1721.
Forms and amounts of soil nitrogen and phosphorus across a longleaf pine-depressional wetland landscape.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BD38Xnt1GqsL0%3D&md5=ce0d6ab9827e0aa104f8e0b6336217b2CAS |

Craft, C. B., and Richardson, C. J. (1998). Recent and long-term organic soil accretion and nutrient accumulation in the Everglades. Soil Science Society of America Journal 62, 834–843.
Recent and long-term organic soil accretion and nutrient accumulation in the Everglades.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DyaK1cXks1eqt7o%3D&md5=94f4b532aebd68cd1a044bf75a9302c5CAS |

Dahl, T. E. (2011). ‘Status and Trends of Wetlands in the Conterminous United States 2004 to 2009.’ (Department of the Interior, Fish and Wildlife Service: Washington, DC, USA.)

Dodla, S. K., Wang, J. J., DeLaune, R. D., and Cook, R. L. (2008). Denitrification potential and its relation to organic carbon quality in three coastal wetland soils. The Science of the Total Environment 407, 471–480.
Denitrification potential and its relation to organic carbon quality in three coastal wetland soils.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BD1cXhsVWhsr7M&md5=6bb38b3efb1b1eb38ee1e0f33cb06a16CAS |

Dunne, E. J., Smith, J., Perkins, D. B., Clark, M. W., Jawitz, J. W., and Reddy, K. R. (2007). Phosphorus storages in historically isolated wetland ecosystems and surrounding pasture uplands. Ecological Engineering 31, 16–28.
Phosphorus storages in historically isolated wetland ecosystems and surrounding pasture uplands.Crossref | GoogleScholarGoogle Scholar |

Efremova, T. T., Sukhorukov, F. V., Efremov, S. P., and Budashkina, V. V. (2002). Accumulation of Cs-137 in peatbogs on the Ob and Tom’ river interfluve. Eurasian Soil Science 35, 91–98.

Eswaran, H., Van Den Berg, E., and Reich, P. (1993). Organic carbon in soils of the World. Soil Science Society of America Journal 57, 192–194.
Organic carbon in soils of the World.Crossref | GoogleScholarGoogle Scholar |

Evenson, G. R., Golden, H. E., Lane, C. R., and D’Amico, E. (2015). Geographically isolated wetlands and watershed hydrology: a modified model analysis. Journal of Hydrology 529, 240–256.
Geographically isolated wetlands and watershed hydrology: a modified model analysis.Crossref | GoogleScholarGoogle Scholar |

Evenson, G. R., Golden, H. E., Lane, C. R., and D’Amico, E. (2016). An improved representation of geographically isolated wetlands in a watershed-scale hydrologic model. Hydrological Processes 30, 4168–4184.
An improved representation of geographically isolated wetlands in a watershed-scale hydrologic model.Crossref | GoogleScholarGoogle Scholar |

Fossey, M. R., Alain, N., Bensalma, F., Savary, S., and Royer, A. (2015). Integrating isolated and riparian wetland modules in the PHYSITEL/HYDROTEL modelling platform: model performance and diagnosis. Hydrological Processes 29, 4683–4702.
Integrating isolated and riparian wetland modules in the PHYSITEL/HYDROTEL modelling platform: model performance and diagnosis.Crossref | GoogleScholarGoogle Scholar |

Foti, R., del Jesus, M., Rinaldo, A., and Rodriguez-Iturbe, I. (2012). Hydroperiod regime controls the organization of plant species in wetlands. Proceedings of the National Academy of Sciences, USA 109, 19596–19600.
Hydroperiod regime controls the organization of plant species in wetlands.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BC38XhvVChurvO&md5=1f4562440ed18d66db50beca7dec85cbCAS |

Freeland, J. A., Richardson, J. L., and Foss, L. A. (1999). Soil indicators of agricultural impacts on northern Prairie wetlands: cottonwood Lake research area, North Dakota, USA. Wetlands 19, 56–64.
Soil indicators of agricultural impacts on northern Prairie wetlands: cottonwood Lake research area, North Dakota, USA.Crossref | GoogleScholarGoogle Scholar |

Gleason, R. A., Tangen, B. A., Laubhan, M. K., Kermes, K. E., and Euliss, N. H. (2007). Estimating water storage capacity of existing and potentially restorable wetland depressions in a subbasin of the Red River of the North. Open File Report 2007–1159. US Geological Survey: Reston, VA, USA.

Golden, H. E., Lane, C. R., Amatya, D. M., Bandilla, K. W., Raanan-Kiperwas, H., Knightes, C. D., and Ssegane, H. (2014). Hydrologic connectivity between geographically isolated wetlands and surface water systems: a review of select modeling methods. Environmental Modelling & Software 53, 190–206.
Hydrologic connectivity between geographically isolated wetlands and surface water systems: a review of select modeling methods.Crossref | GoogleScholarGoogle Scholar |

Hey, D. L. (2002). Nitrogen farming: harvesting a different crop. Restoration Ecology 10, 1–10.
Nitrogen farming: harvesting a different crop.Crossref | GoogleScholarGoogle Scholar |

Johnston, C. A. (1991). Sediment and nutrient retention by freshwater wetlands: effects on surface water quality. Critical Reviews in Environmental Control 21, 491–565.
Sediment and nutrient retention by freshwater wetlands: effects on surface water quality.Crossref | GoogleScholarGoogle Scholar |

Kushlan, J. A. (1990). Freshwater marshes. In ‘Ecosystems of Florida’. (Eds R. L. Myers and J. J. Ewel.) pp. 323–363. (University of Central Florida Press: Orlando, FL, USA.)

Lane, C. R., and Autrey, B. C. (2016). Phosphorus retention of forested and emergent marsh depressional wetlands in differing land uses in Florida, USA. Wetlands Ecology and Management 24, 45–60.
Phosphorus retention of forested and emergent marsh depressional wetlands in differing land uses in Florida, USA.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BC2MXhtlCrtrvN&md5=c56fd00080dfdd5b48d5e32e62278d9eCAS |

Lane, C. R., and D’Amico, E. (2016). Potential geographically isolated wetlands of the Conterminous United States. Journal of the American Water Resources Association 52, 705–722.
Potential geographically isolated wetlands of the Conterminous United States.Crossref | GoogleScholarGoogle Scholar |

Lane, C. R., D’Amico, E., and Autrey, B. (2012). Isolated wetlands of the southeastern United States: abundance and expected condition. Wetlands 32, 753–767.
Isolated wetlands of the southeastern United States: abundance and expected condition.Crossref | GoogleScholarGoogle Scholar |

Lane, C. R., Autrey, B. C., Jicha, T., Lehto, L., Elonen, C., and Seifert-Monson, L. (2015). Denitrification potential in geographically isolated wetlands of North Carolina and Florida, USA. Wetlands 35, 459–471.
Denitrification potential in geographically isolated wetlands of North Carolina and Florida, USA.Crossref | GoogleScholarGoogle Scholar |

Leibowitz, S. (2015). Geographically isolated wetlands: why we should keep the term. Wetlands 35, 997–1003.
Geographically isolated wetlands: why we should keep the term.Crossref | GoogleScholarGoogle Scholar |

Liess, A., and Hillebrand, H. (2005). Stoichiometric variation in C : N, C : P, and N : P ratios of littoral benthic invertebrates. Journal of the North American Benthological Society 24, 256–269.
Stoichiometric variation in C : N, C : P, and N : P ratios of littoral benthic invertebrates.Crossref | GoogleScholarGoogle Scholar |

Likens, G. E., Zedler, J., Mitsch, B., Sharitz, R., Larson, J., Fredrickson, L., Pimm, S., Semlitsch, R., Bohlen, C., Woltemade, C., Hirschfeld, M., Callaway, J., Huffman, T., Bancroft, T., Richter, K., Teal, J., and the Association of State Wetland Managers (2000). Brief for Dr Gene Likens et al., as Amici Curiae of Writ of Certiorari to the United States Court of Appeals for the Seventh Circuit. Solid Waste Agency of Northern Cook County v. US Army Corps of Engineers, number 99-1178. Submitted by T. D. Searchinger and M. J. Bean, attorneys for Amici Curiae. Available at http://supreme.findlaw.com/supreme_court/briefs/99-1178/99-1178fo21/text.html [Verified 27 June 2017].

Marín-Muñiz, J. L., Hernandez, M. E., and Moreno-Casasola, P. (2014). Comparing soil carbon sequestration in coastal freshwater wetlands with various geomorphic features and plant communities in Veracruz, Mexico. Plant and Soil 378, 189–203.
Comparing soil carbon sequestration in coastal freshwater wetlands with various geomorphic features and plant communities in Veracruz, Mexico.Crossref | GoogleScholarGoogle Scholar |

Marton, J. M., Creed, I., Lewis, D., Lane, C. R., Basu, N., Cohen, M. J., and Craft, C. (2015). Geographically isolated wetlands are important biogeochemical reactors on the landscape. Bioscience 65, 408–418.
Geographically isolated wetlands are important biogeochemical reactors on the landscape.Crossref | GoogleScholarGoogle Scholar |

McCauley, L. A., Jenkins, D. G., and Quintana-Ascencio, P. F. (2013). Isolated wetland loss and degradation over two decades in an increasingly urbanized landscape. Wetlands 33, 117–127.
Isolated wetland loss and degradation over two decades in an increasingly urbanized landscape.Crossref | GoogleScholarGoogle Scholar |

McLaughlin, D. L., Kaplan, D. A., and Cohen, M. J. (2014). A significant nexus: geographically isolated wetlands influence landscape hydrology. Water Resources Research 50, 7153–7166.
A significant nexus: geographically isolated wetlands influence landscape hydrology.Crossref | GoogleScholarGoogle Scholar |

Miller, R. C., and Zedler, J. B. (2003). Responses of native and invasive wetland plants to hydroperiod and water depth. Plant Ecology 167, 57–69.
Responses of native and invasive wetland plants to hydroperiod and water depth.Crossref | GoogleScholarGoogle Scholar |

Mushet, D., Calhoun, A. J. K., Alexander, L. C., Cohen, M. J., DeKeyser, E. S., Fowler, L., Lane, C. R., Lang, M. W., Rains, M. C., and Walls, S. C. (2015). Geographically isolated wetlands: rethinking a misnomer. Wetlands 35, 423–431.
Geographically isolated wetlands: rethinking a misnomer.Crossref | GoogleScholarGoogle Scholar |

Omernik, J. M. (1987). Ecoregions of the Conterminous United States. Annals of the Association of American Geographers 77, 118–125.
Ecoregions of the Conterminous United States.Crossref | GoogleScholarGoogle Scholar |

Pribyl, D. (2010). A critical review of the conventional SOC to SOM conversion factor. Geoderma 156, 75–83.
A critical review of the conventional SOC to SOM conversion factor.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BC3cXltF2rsrw%3D&md5=58ea457fd5da3be2a3552397d977cf9fCAS |

Rains, M. C., Leibowitz, S. G., Cohen, M. J., Creed, I. F., Golden, H. E., Jawitz, J. W., Kalla, P., Lane, C. R., Lang, M. W., and McLaughlin, D. L. (2016). Geographically isolated wetlands are part of the hydrological landscape. Hydrological Processes 30, 153–160.
Geographically isolated wetlands are part of the hydrological landscape.Crossref | GoogleScholarGoogle Scholar |

Reddy, K. R., and DeLaune, R. D. (2008). ‘Biogeochemistry of Wetlands: Science and Applications.’ (CRC Press: Boca Raton, FL, USA.)

Reddy, K. R., Delaune, R. D., Debusk, W. F., and Koch, M. S. (1993). Long-term nutrient accumulation rates in the Everglades. Soil Science Society of America Journal 57, 1147–1155.
Long-term nutrient accumulation rates in the Everglades.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DyaK2cXhvF2ksbo%3D&md5=f5d1c6e812caeb0fe2f4b6b838e401d4CAS |

Ritchie, J. C., and McHenry, J. R. (1990). Application of radioactive fallout cesium-137 for measuring soil erosion and sediment accumulation rates and patterns: a review. Journal of Environmental Quality 19, 215–233.
Application of radioactive fallout cesium-137 for measuring soil erosion and sediment accumulation rates and patterns: a review.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DyaK3cXksVGrs74%3D&md5=7760f36e2c6ce5f897d02fcf1ce205d4CAS |

Serran, J., and Creed, I. F. (2016). New mapping techniques to estimate the preferential loss of small wetlands on prairie landscapes. Hydrological Processes 30, 396–409.
New mapping techniques to estimate the preferential loss of small wetlands on prairie landscapes.Crossref | GoogleScholarGoogle Scholar |

Sharitz, R. R., and Gresham, C. A. (1998). Pocosins and Carolina Bays. In ‘Southern Forested Wetlands’. (Eds M. G. Messina and W. H. Conner.) pp. 343–377. (Lewis Publishers: Boca Raton, FL, USA.)

Sun, G., Riekerk, H., and Korhnak, L. V. (1995). Shallow groundwater table dynamics of cypress wetland pine upland systems in Florida flatwoods. Proceedings - Soil and Crop Science Society of Florida 54, 66–71.

Tiner, R. W. (2003a). Geographically isolated wetlands of the United States. Wetlands 23, 494–516.
Geographically isolated wetlands of the United States.Crossref | GoogleScholarGoogle Scholar |

Tiner, R. W. (2003b). Estimated extent of geographically isolated wetlands in selected areas of the United States Wetlands 23, 636–652.
Estimated extent of geographically isolated wetlands in selected areas of the United StatesCrossref | GoogleScholarGoogle Scholar |

Ullah, S., and Faulkner, S. P. (2006). Denitrification potential of different land-use types in an agricultural watershed, lower Mississippi valley. Ecological Engineering 28, 131–140.
Denitrification potential of different land-use types in an agricultural watershed, lower Mississippi valley.Crossref | GoogleScholarGoogle Scholar |

US EPA (2015). ‘Connectivity of Streams and Wetlands to Downstream Waters: a Review and Synthesis of the Scientific Evidence. EPA/600/R-14/475F.’ (US EPA Office of Research and Development: Washington, DC, USA.)

Van Meter, K. J., and Basu, N. B. (2015). Signatures of human impact: size distributions and spatial organization of wetlands in the Prairie Pothole landscape. Ecological Applications 25, 451–465.
Signatures of human impact: size distributions and spatial organization of wetlands in the Prairie Pothole landscape.Crossref | GoogleScholarGoogle Scholar |

Zhang, Y., Lu, X., Shao, X., Chen, C., Li, X., Zhao, F., Li, G., and Matsumoto, E. (2016). Temporal variation of sedimentation rates and potential factors influencing those rates over the last 100 years in Bohai Bay, China. The Science of the Total Environment 572, 68–76.
Temporal variation of sedimentation rates and potential factors influencing those rates over the last 100 years in Bohai Bay, China.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BC28Xht12lt7%2FN&md5=0c1b0e4f6bb0234e140771df500baae4CAS |