This data package was submitted to a staging environment for testing purposes only. Use of these data for anything other than testing is strongly discouraged.

Data Package Summary    View Full Metadata

  • Pore water concentrations of Nitrogen from N-Addition plots in an Alberta Poor Fen, 2011-2015
  • Wieder, R Kelman; Villanova University
    Vitt, Dale H; Southern Illinois University
    Vile, Melanie A; Villanova University
    Graham, Jeremy A; Southern Illinois University
    Hartsock, Jeremy A; Southern Illinois University
    Popma, Jacqueline M.A.; University of Michigan
    Fillingim, Hope; Villanova University
    House, Melissa; Southern Illinois University
    Quinn, James C; Villanova University
    Scott, Kimberli D; Villanova University
    Petix, Meaghan; Southern Illinois University
    McMillen, Kelly J; Villanova University
  • 2020-03-02
  • Wieder, R.K., D.H. Vitt, M.A. Vile, J.A. Graham, J.A. Hartsock, J.M. Popma, H. Fillingim, M. House, J.C. Quinn, K.D. Scott, M. Petix, and K.J. McMillen. 2020. Pore water concentrations of Nitrogen from N-Addition plots in an Alberta Poor Fen, 2011-2015 ver 1. Environmental Data Initiative. https://doi.org/DOI_PLACE_HOLDER (Accessed 2024-12-27).
  • Development of the oil sands has led to increasing atmospheric N deposition, with values as high as 17 kg N ha-1 yr-1; regional background levels <2 kg N ha-1 yr-1. To examine responses to N deposition, over five years, we experimentally applied N (as NH4NO3) to a poor fen near Mariana Lake, Alberta, at rates of 0, 5, 10, 15, 20, and 25 kg N ha-1 yr-1, plus controls (no water or N addition). We collected surface pore water from all plots several times a year throughout the 5 year experiment. Over the 5 years of the study, porewater NH4+-N, NO3--N, and DON concentrations at the top of the poor fen water table were unaffected by N addition (p = 0.06, 0.30, 0.16, respectively). However, porewater NH4+-N, NO3--N, and DON concentrations were substantially higher in 2011 than in 2012-2015 (Fig. 11). Water addition alone had no significant effect on porewater concentrations of NH4+-N, NO3--N, or DON (p > 0.99).

    We hypothesized that as N deposition increases to a level that exceeds the capacity of the fen vegetation to take up N, net N mineralization in surface peat would be inhibited by higher NH4+-N availability, net nitrification would be stimulated by higher NH4+-N availability, and concentrations of DIN in porewater at the top of the water table would increase, as DIN bypasses interception by the ground layer vegetation. None of these hypotheses was supported with nitrogen being immediately taken up by vegetation. It is unclear if longer term study would reveal similar responses.

  • N: 55.897      S: 55.897      E: -112.094      W: -112.094
  • edi.348.1  (Uploaded 2020-03-02)  
  • This data package is released to the "public domain" under Creative Commons CC0 1.0 "No Rights Reserved" (see: https://creativecommons.org/publicdomain/zero/1.0/). It is considered professional etiquette to provide attribution of the original work if this data package is shared in whole or by individual components. A generic citation is provided for this data package on the website https://portal.edirepository.org (herein "website") in the summary metadata page. Communication (and collaboration) with the creators of this data package is recommended to prevent duplicate research or publication. This data package (and its components) is made available "as is" and with no warranty of accuracy or fitness for use. The creators of this data package and the website shall not be liable for any damages resulting from misinterpretation or misuse of the data package or its components. Periodic updates of this data package may be available from the website. Thank you.
  • DOI PLACE HOLDER
  • Analyze this data package using:           

EDI is a collaboration between the University of New Mexico and the University of Wisconsin – Madison, Center for Limnology:

UNM logo UW-M logo