Advances in engineered remediation for use in the Arctic and Antarctica

D.M. Filler; C.M. Reynolds; I. Snape; A.J. Daugulis; D.L. Barnes; P.J. Williams

doi:10.1017/S003224740500505X

Abstract

Creative remediation schemes have been implemented with success at petroleum-contaminated sites in Alaska and Canada during the past decade. Contaminated media have been landfarmed, amended with fertilizers, augmented with microbial products, and manipulated with engineered systems. Phytoremediation developments and use of biodegradable synthetic and polymeric resins for potential use with petroleum and xenobiotic contaminants are on the horizon. Treatment of supra-permafrost water and melt-water runoff with permeable reactive barriers and partitioning bioreactors is now possible. Cost and time limitations will likely continue to drive remediation decisions in the Arctic. Environmental policy, environmental constraints, and cost will dictate what technologies are appropriate for Antarctic clean-up, although the pressure of time is less acute because land transfer and liability are not drivers. This paper discusses some recent advances in remediation engineering for use in polar regions. Conceptual models are presented, and case study treatment costs and durations are highlighted to aid environmental decision-making.

Crossref Citations

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Rayner, John L. Snape, Ian Walworth, James L. Harvey, Paul McA. and Ferguson, Susan H. 2007. Petroleum–hydrocarbon contamination and remediation by microbioventing at sub-Antarctic Macquarie Island. Cold Regions Science and Technology, Vol. 48, Issue. 2, p. 139.

Van Stempvoort, Dale and Biggar, Kevin 2008. Potential for bioremediation of petroleum hydrocarbons in groundwater under cold climate conditions: A review. Cold Regions Science and Technology, Vol. 53, Issue. 1, p. 16.

YANG, Si-Zhong JIN, Hui-Jun WEI, Zhi HE, Rui-Xia JI, Yan-Jun LI, Xiu-Mei and YU, Shao-Peng 2009. Bioremediation of Oil Spills in Cold Environments: A Review. Pedosphere, Vol. 19, Issue. 3, p. 371.

Filler, Dennis M. Van Stempvoort, Dale R. and Leigh, Mary B. 2009. Permafrost Soils. Vol. 16, Issue. , p. 279.

Margesin, Rosa and Feller, Georges 2010. Biotechnological applications of psychrophiles. Environmental Technology, Vol. 31, Issue. 8-9, p. 835.

Yang, Chaowei Nebert, Doug and Fraser Taylor, D.R. 2011. Establishing a sustainable and cross-boundary geospatial cyberinfrastructure to enable polar research. Computers & Geosciences, Vol. 37, Issue. 11, p. 1721.

Mair, J. Schinner, F. and Margesin, R. 2013. A feasibility study on the bioremediation of hydrocarbon-contaminated soil from an Alpine former military site: Effects of temperature and biostimulation. Cold Regions Science and Technology, Vol. 96, Issue. , p. 122.

Leewis, Mary-Cathrine Reynolds, Charles M. and Leigh, Mary Beth 2013. Long-term effects of nutrient addition and phytoremediation on diesel and crude oil contaminated soils in subarctic Alaska. Cold Regions Science and Technology, Vol. 96, Issue. , p. 129.

Camenzuli, Danielle and Gore, Damian B. 2013. Immobilization and Encapsulation of Contaminants Using Silica Treatments: A Review. Remediation Journal, Vol. 24, Issue. 1, p. 49.

Naseri, Masoud Barabadi, Abbas and Barabady, Javad 2014. Bioremediation treatment of hydrocarbon-contaminated Arctic soils: influencing parameters. Environmental Science and Pollution Research, Vol. 21, Issue. 19, p. 11250.

Filler, D.M. Kennicutt, Mahlon C. Snape, Ian Sweet, Stephen T. and Klein, Andrew G. 2014. Handbook of Oil Spill Science and Technology. p. 495.

Yates, Colin N. Balch, Gordon C. and Wootton, Brent C. 2014. Ecological Modelling and Engineering of Lakes and Wetlands. Vol. 26, Issue. , p. 539.

McDonald, Roseanne and Knox, Oliver G. G. 2014. Cold Region Bioremediation of Hydrocarbon Contaminated Soils: Do We Know Enough?. Environmental Science & Technology, Vol. 48, Issue. 17, p. 9980.

Feller, Georges and Margesin, Rosa 2014. Polar Microbiology. p. 166.

Richardson, Elizabeth L King, Catherine K and Powell, Shane M 2015. The use of microbial gene abundance in the development of fuel remediation guidelines in polar soils. Integrated Environmental Assessment and Management, Vol. 11, Issue. 2, p. 235.

Camenzuli, Danielle 2015. Minerals Formed by Treatment of Heavy Metals with Orthophosphate, Silica or an Orthophosphate-Silica Mix Treatment under Cold Conditions. International Journal of Environmental Science and Development, Vol. 6, Issue. 12, p. 913.

Camenzuli, Danielle and Freidman, Benjamin L. 2015. On-site and in situ remediation technologies applicable to petroleum hydrocarbon contaminated sites in the Antarctic and Arctic. Polar Research, Vol. 34, Issue. 1, p. 24492.

Freidman, Benjamin L. Gras, Sally L. Snape, Ian Stevens, Geoff W. and Mumford, Kathryn A. 2016. Application of controlled nutrient release to permeable reactive barriers. Journal of Environmental Management, Vol. 169, Issue. , p. 145.

Freidman, Benjamin L. Gras, Sally L. Snape, Ian Stevens, Geoff W. and Mumford, Kathryn A. 2016. Effects of Freeze–Thaw Phenomena on Controlled Nutrient Release: Application to Bioremediation. CLEAN – Soil, Air, Water, Vol. 44, Issue. 12, p. 1739.

Camenzuli, Danielle Wise, Lauren E. Stokes, Alex J. and Gore, Damian B. 2017. Treatment of soil co-contaminated with inorganics and petroleum hydrocarbons using silica: Implications for remediation in cold regions. Cold Regions Science and Technology, Vol. 135, Issue. , p. 8.

Download full list

Article contents

Advances in engineered remediation for use in the Arctic and Antarctica

Abstract

Access options

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Article contents

Advances in engineered remediation for use in the Arctic and Antarctica

Abstract

Access options

Save article to Kindle

Save article to Dropbox

Save article to Google Drive

Reply to: Submit a response

Your details

You have entered the maximum number of contributors

Conflicting interests