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Evaluation of Three Soil Blends to Improve Ornamental Plant Performance and Maintain Engineering Metrics in Bioremediating Rain Gardens

  • James T. FunaiEmail author
  • Petr Kupec
Article
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Abstract

This research project explores the performance of soils intended to support ornamental plants serving an ecological benefit within bioremediating rain gardens. Three plots of identical plantings were installed in autumn of 2015 into three different planting media in Northeast Ohio, USA. A control soil blend was tested against two experimental soil blends in the field under natural conditions for 3 years to explore any potential differences in overall plant performance. The control planting soil was created following current Ohio Department of Natural Resources specifications for rain garden planting soils which consist of no less than 80% sand and no more than 10% clay by volume. Test soil blends incorporated lightweight expanded shale to combat the potential negative effects of high sand soils for plants (i.e., high matric potential) while maintaining required engineering benefits (i.e., fast infiltration rate coupled with good physical, chemical, and biological filtration). Our analysis suggests that incorporating expanded shales into bioremediating gardens as a replacement to high sand content can maintain all engineering specifications and may increase survival rates of plant life beyond rates currently found in high sand content rain gardens. Survival rate for plants in the control plot was at 48.3% while experimental plots one and two were 96.5% and 75.8% respectively. The research team suggests that these increased survival rates could contribute to more widespread adoption and implementation of stormwater management practices, especially small-scale, interconnected rain gardens in the urban environment as designated by low-impact development standards.

Keywords

Bioremediation Stormwater management practices Rain gardens Low-impact development Lightweight expanded shale Bioretention 

Notes

Acknowledgements

The research team would like to thank Mr. Bill Hendricks of Klyn Nursery for the donation of all plant materials utilized in the study.

Compliance with Ethical Standards

Conflict of Interest

The authors declare that they have no competing interests.

References

  1. Ambrose, R. F., & Winfrey, B. K. (2015). Comparison of stormwater biofiltration systems in Southeast Australia and Southern California. Wiley Interdisilplinary Reviews: Water, 2(2), 131–146.  https://doi.org/10.1002/wat2.1064.CrossRefGoogle Scholar
  2. Askarizadeh, A., Rippy, M. A., Fletcher, T. D., Feldman, D., Peng, J., Bowler, P., et al. (2015). From rain tanks to catchments: use of low impact development to address hydrologic symptoms of the urban stream syndrome. Environmental Science & Technology, 49(19), 11264–11280.  https://doi.org/10.1021/ACS.EST.5B01635.CrossRefGoogle Scholar
  3. Asleson, B. C., Gulliver, J. S., Hozalski, R. M., Nestingen, R. S., & Nieber, J. L. (2009). Performance assessment of rain gardens. Journal of the American Water Resources Association, 45(4), 1019–1031.  https://doi.org/10.1111/j.1752-1688.2009.00344.x.CrossRefGoogle Scholar
  4. Björklund, K., & Li, L. (2017). Removal of organic contaminants in bioretention medium amended with activated carbon from sewage sludge. Environmental Science and Pollution Research, 24(23), 19167–19180.  https://doi.org/10.1007/S11356-017-9508-1.CrossRefGoogle Scholar
  5. Bratieres, K., Fletcher, T. D., Deletic, A., & Zinger, Y. (2008). Nutrient and sediment removal by stormwater biofilters: a large scale design optimization study. Water Reserach (42), 3930–3940.Google Scholar
  6. Brix, H., Arias, C., & del Bubba, M. (2001). Media selection for sustainable phosphorus removal in subsurface flow constructed wetlands. Water Science and Technology, 44(11–12), 47–54.CrossRefGoogle Scholar
  7. Brown, J., & Peake, B. (2006). Sources of heavy metals and polycyclic aromatic hydrocarbons in urban stormwater runoff. Science of the Total Environment, 359(1–3), 145–155.CrossRefGoogle Scholar
  8. Christianson, R., Barfield, B., Hayes, J., Gasem, K., & Brown, G. (2004). Modeling effectiveness of bioretention cells for control of stormwater quantity and quality. Critical Transistions in Water and Enviornmental Resources Managment, 37, 1–7.  https://doi.org/10.1061/40737.CrossRefGoogle Scholar
  9. Davis Instruments. (2018). Davis Vantage Pro2. Retrieved from Davis Instruments: https://www.davisinstruments.com/solution/vantage-pro2/
  10. Dietz, M., & Clausen, J. (2005). A field evaluation of rain garden flow and pollutant treatment. Water, Air, and Soil Pollution, 1(4), 123–138.CrossRefGoogle Scholar
  11. DiGeronimo Aggregates LLC. (2018). Technical information on Haydite. Retrieved from DiGeronimo Aggregates LLC: http://www.digagg.com/technical_info/
  12. Donovan, T., Lowndes, M., McBrien, P., & Pfender, J. (2015). The Wisconsin storm water manual, Technical Design Guidelines for Storm Water Management Practices. Wisconsin Department of Natural Resources.Google Scholar
  13. Eckart, K., McPhee, Z., & Bolisetti, T. (2017). Performance and implementation of low impact development—a review. Science of the Total Environment, 607-608, 413–432.  https://doi.org/10.1016/J.SCITOTENV.2017.06.254.CrossRefGoogle Scholar
  14. Erickson, A. J., Weiss, P. T., & Gulliver, J. S. (2013). Optimizing stormwater treatment practices: a handbook of assessment and maintenance. New York: Springer.CrossRefGoogle Scholar
  15. Expanded Shale, Clay and Slate Institute. (2018). ESCS lightweight aggregate. Retrieved from Expanded Shale, Clay and Slate Institute: https://www.escsi.org/escs-lwa/
  16. Forbes, M. G., Dickson, K. L., Saleh, F., Doyle, R. D., & Hudak, P. (2005). Recovery and fractionation of phosphorus retained by lightweight expanded shale and masonry sand used as media in subsurface flow treatment wetlands. Environmental Science and Technology, 39(12), 4621–4627.  https://doi.org/10.1021/es048149o.CrossRefGoogle Scholar
  17. Hunt, W. F., & White, N. (2001). Designing rain gardens Ag-588-03. North Carolina State University, Department of Biological and Agricultural Engineering. In North Carolina Cooperative Extension Service.Google Scholar
  18. Irrometer. (2018, 7 26). Understanding soil moisture. Retrieved from Irrometer Corporation: http://www.irrometer.com/basics.html
  19. Kaplan, R., & Kaplan, S. (1989). The experience of nature: a psychological perspective. Cambridge: Cambridge University Press.Google Scholar
  20. Kasaraneni, V. K., Schifman, L. A., Boving, T. B., & Oyanedel-Craver, V. (2014). Enhancement of surface runoff quality using modified sorbents. ACS Sustainable Chemistry and Engineering, 2(7), 1609–1615.  https://doi.org/10.1021/SC500107Q.CrossRefGoogle Scholar
  21. Kryzanowski, L. (2017). Guide to field experimentation. Alberta, Canada Ministry of Agriculture and Forestry, Department of Agriculture. Edmonton: Alberta Ministry of Agriculture and Forestry Retrieved from https://www1.agric.gov.ab.ca/$department/deptdocs.nsf/all/sag3024
  22. Langeveld, J. G., Liefting, H. J., & Boogaard, F. C. (2012). Uncertainties of stormwater characteristics and removal rates of stormwater treatment facilities: implications for stormwater handling. Water Research, 46(20), 6868–6880.  https://doi.org/10.1016/J.WATRES.2012.06.001.CrossRefGoogle Scholar
  23. Law, E. P., Diemont, S. A., & Toland, T. R. (2017). A sustainability comparison of green infrastructure interventions using emergy evaluation. Journal of Cleaner Production, 145, 374–385.  https://doi.org/10.1016/J.JCLEPRO.2016.12.039.CrossRefGoogle Scholar
  24. Leib, B. G., Jabro, J. D., & Matthews, G. R. (2003). Field evaluation and performance comparison of soil moisture sensors. Soil Science, 168(6), 396–408.Google Scholar
  25. Mangangka, I. R., Liu, A., Egodawatta, P., & Goonetilleke, A. (2015). Performance characterisation of a stormwater treatment bioretention basin. Journal of Environmental Management, 150, 173–178.  https://doi.org/10.1016/J.JENVMAN.2014.11.007.CrossRefGoogle Scholar
  26. Maryland Department of the Environment. (2009). Maryland stormwater design manual. Maryland Department of the Environment.Google Scholar
  27. Mathews, J. (2014). Rainwater and land development: Ohio’s Standards For Stormwater Management, Land Development And Urban Stream Protection. Ohio Department of Natural Resources, Division of Soil and Water Conservation. Columbus: Ohio Department of Natural Resources Retrieved from http://oilandgas.ohiodnr.gov/portals/oilgas/pdf/stormwater/rld_11-6-14all.pdf
  28. ODNR. (2014). Rainwater and land development: Ohio’s standards for stormwater managment, land development, and urban stream protection. Divsion of Soil and Water Conservation. Columbus: Ohio Department of Natural Resources.Google Scholar
  29. Payne, E., Hatt, B., Deletic, A., Dobbie, M., McCarthy, D., & Chandrasena, G. (2015). Adoption guidelines for stormwater biofiltration systems—summary report. Cooperative Research Centre for Water Sensitive Cities.Google Scholar
  30. Prince George’s County. (1999). Low-impact development design stratagies: an integrated design approach. MD: Department of Environmental Resources. Prince George's County.Google Scholar
  31. Simmons, M. T., Gardiner, B., Windhager, S., & Tinsley, J. (2008). Green roofs are not created equal: the hydrologic and thermal performance of six different extensive green roofs and reflective and non-reflective roofs in a sub-tropical climate. Urban Ecosystems, 11(4), 339–348.CrossRefGoogle Scholar
  32. Taber, H. G., Lawson, V., Smith, B., & Shogren, D. (2002). Scheduling microirrigation with tensiometers or Watermarks. International Water and Irrigation, 22(1), 22–26.Google Scholar
  33. Trenouth, W. R., & Gharabaghi, B. (2015). Soil amendments for heavy metals removal from stormwater runoff discharging to environmentally sensitive areas. Journal of Hydrology, 529, 1478–1487.CrossRefGoogle Scholar
  34. van Groenestijn, J. W., & Liu, J. X. (2002). Removal of alpha-pinene from gases using biofilters containing fungi. Atmospheric Environment, 36(35), 5501–5508.CrossRefGoogle Scholar
  35. Yang, H., Dick, W. A., McCoy, E. L., Phelen, P. L., & Grewal, P. S. (2013). Field evaluation of a new biphasic rain garden for stormwater flow management and pollutant removal. Ecological Engineering, 54, 22–31.  https://doi.org/10.1016/J.ECOLENG.2013.01.005.CrossRefGoogle Scholar

Copyright information

© Springer Nature Switzerland AG 2018

Authors and Affiliations

  1. 1.Cuyahoga Community CollegeHighland HeightsUSA
  2. 2.Mendel UniversityBrno-sever-Černá PoleCzech Republic

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