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Examining thin layer cap behaviour in a freshwater industrial harbour

  • SEDIMENTS, SEC 5 • SEDIMENT MANAGEMENT • RESEARCH ARTICLE
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Abstract

Purpose

A sediment remediation project in Hamilton Harbour, Lake Ontario, Canada, proposes to use a thin layer cap for managing residual contamination from dredging as well as areas of marginal contamination not included in the dredge plan. Bottom shear stress (BSS) from weather, as well as propeller wash, have the potential to severely erode thin layer caps. The proposed thin layer cap was examined with respect to the BSS expected in Hamilton Harbour over a 6-month period.

Materials and methods

BSS from vessels was estimated using published equations and BSS from weather using the MIKE 3 model. Critical shear stress for the capping sand was estimated using established equations and an annular flume.

Results and discussion

Estimated BSS from marine vessels was found to exceed the critical shear stress in most cases. However, the extent of impact was difficult to determine and was mitigated to some extent by short vessel passage times, slightly differing routes and further sediment movement caused by weather. The average estimated BSS from weather for the study period was found to be below the critical shear stress for the capping sand, but the maximum BSS exceeded for a small area of the site.

Conclusions

Apart from the shipping routes, the majority of the capping area should remain well below the critical shear stress. However, consideration of a larger grain size of capping material for the shallow areas should be considered. This would be of value for future storm conditions which might exceed what was experienced during the 6-month study period.

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References

  • Amos CL, Droppo IG (1996) Stability of remediated lakebed sediment, Hamilton Harbour, Lake Ontario, Canada. Open File report No. 2276. Geological Survey of Canada, Ottawa, Canada

  • Amos CL, Li MZ, Sutherland TF (1998) The contribution of ballistic momentum flux to the erosion of cohesive beds by flowing water. J Coastal Res 14:564–569

    Google Scholar 

  • daSilva AMAF, Bolisetti T (2000) A method for the formulation of Reynolds number functions. Can J Civil Engineer 27:829–833

    Article  Google Scholar 

  • Droppo IG (2001) Rethinking what constitutes suspended sediment. Hydrol Process 15:1551–1564

    Article  Google Scholar 

  • Engler R, Saunders L, Wright T (1991) Environmental effects of aquatic disposal of dredged material. Environ Professional 13:317–325

    Google Scholar 

  • Folk RL (1954) The distinction between grain size and mineral composition in sedimentary rock nomenclature. J Geol 62:344–359

    Article  CAS  Google Scholar 

  • Grabowski RC, Droppo IG, Wharton G (2010) Estimation of critical shear stress from cohesive strength meter derived erosion thresholds. Limnol Oceanogr-Meth 8:678–685

    Article  Google Scholar 

  • Graham M, Hartman E, Joyner R, Santiago R (2012) PAH-contaminated sediment remediation: an overview of a proposed large scale clean-up in a freshwater harbour. In: Mulligan (ed). Contaminated Sediments: Restoration of Aquatic Environment on May 23–25, 2012 in Montreal, Quebec, Canada; STP 1554. ASTM International, West Conshohocken, PA. pp 1–23. DOI:10.1520/STP104354

  • Hayes DF, Chintamaneni R, Bommareddy P, Cherukuri B (2012) Vessel-induced sediment resuspension. J Dredging Engineer 12:1–23

    Google Scholar 

  • He C, Rao YR, Marvin CH (2012) Numerical modeling study of hydraulic impact of a large sediment capping facility. J Hydraulic Engineer 138:642–652

    Article  Google Scholar 

  • Irvine KN, Droppo IG, Murphy TP, Lawson A (1997) Sediment resuspension and dissolved oxygen levels associated with ship traffic: implications for habitat remediation. Water Qual Res J Can 32:421–437

    CAS  Google Scholar 

  • Lau YL, Droppo IG (2000) Influence of antecedent conditions on critical shear stress of bed sediments. Water Res 34:663–667

    Article  CAS  Google Scholar 

  • Liou Y-C, Herbich JB (1976) Sediment movement induced by ships in restricted waterways. TAMU-SG-76-209, COE Report No. 188 Texas A&M University, USA

  • Maurer DL, Keck RT, Tinsman JC, Leathern WA, Wethe CA, Hunt-Zinger M, Lord C, Church TM (1978) Vertical migration of benthos I simulated dredged material overburden. Volume 1: marine benthos. Technical Report D-78-35(NTIS No.AD-A058725) U.S. Army Engineer Waterways Experimental Station, Vicksburg, MS, USA

  • Maurer DL, Keck RT, Tinsman JC, Leathern WA (1981a) Vertical migration and mortality of benthos in dredged material: part I—mollusca. Mar Environ Res 4:299–319

    Article  Google Scholar 

  • Maurer DL, Keck RT, Tinsman JC, Leathern WA (1981b) Vertical migration and mortality of benthos in dredged material: part II—crustacea. Mar Environ Res 5:301–317

    Article  Google Scholar 

  • Maurer DL, Keck RT, Tinsman JC, Leathern WA (1982) Vertical migration and mortality of benthos in dredged material: part III—polychaeta. Mar Environ Res 6:49–68

    Article  Google Scholar 

  • Nichols JA, Rowe GT, Clifford CH, Young RA (1978) In situ experiments on the burial of marine invertebrates. J Sediment Petrol 48:419–425

    Google Scholar 

  • Oliver JS, Slattery PN, Hulberg LW, Nybakken W (1977) Patterns of succession in benthic infaunal communities following dredging and dredged material disposal in Monterey Bay. Contract Report D-77-27(NTIS No. AD-A049632). U.S. Army Engineer Waterways Experimental Station, Vicksburg, MS, USA

  • Palermo M, Maynord S, Miller J, Reible D (1998) Assessment and Remediation of Contaminated Sediment (ARCS) Program—guidance for in-situ subaqueous capping of contaminated sediments. Appendix A. US Environmental Protection Agency, EPA 905 B96-004, USA

  • Palermo M, Schroeder PR, Estes JR, Francingues NR (2008) Technical guidelines for environmental dredging of contaminated sites. U.S. Army Corps of Engineers Engineer Research and Development Centre—ERDC/EL TR-08-29, USA

  • Reible D, Hayes D, Lue-Hing C, Patterson J, Bhownik N, Johnson M, Teal J (2003) Comparison of the long-term risk of removal and in situ management of contaminated sediments in the Fox River. Soil Sediment Contam 12:325–344

    Article  Google Scholar 

  • Rukavina NA, Versteeg JK (1995) The physical properties of the surficial sediments of Hamilton Harbour. National Water Research Institute Contribution No. 95-150, NWRI, Burlington, Canada

  • Zeman AJ (1994) Subaqueous capping of very soft contaminated sediments. Can Geotech J 31:570–577

    Article  Google Scholar 

  • Zeman AJ, Graham JE (1991) Design considerations for subaqueous capping in Hamilton Harbour—impact velocity of sand and sand penetration into very soft cohesive sediments. National Water Research Institute Contribution No. 91-26, NWRI, Burlington, Canada

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Correspondence to Matt Graham.

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Responsible editor: Gijs D. Breedveld

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Graham, M., Hartman, E., He, C. et al. Examining thin layer cap behaviour in a freshwater industrial harbour. J Soils Sediments 13, 1515–1526 (2013). https://doi.org/10.1007/s11368-013-0749-4

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  • DOI: https://doi.org/10.1007/s11368-013-0749-4

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