Abstract
Sediment losses as concentrations and yields were measured for a year from 12 segments of a newly constructed (buried) natural gas pipeline on the US Forest Service’s Fernow Experimental Forest in West Virginia. Pipeline segments were separated by waterbars which served as drainage features. Six segments were northwest-facing, and six were southeast-facing. Three segments on each aspect were seeded with warm season native herbaceous species at rates used by the Forest Service (1×). All remaining segments received seeding at three times that rate (3×). Forest Service-established rates of fertilizer, lime, and straw mulch were applied to all segments. Sediment concentrations and yields generally were highest at the start of the study, respectively, averaging approximately 1660 mg L−1 and 340 kg ha−1 during the first 3 months following completion of corridor reclamation, but they were less than from nearby less-steep forest road corridors. Concentrations and yields fell significantly after the first 3 months; declines were attributed to revegetation on the ROW. At the end of the first growing season, vegetative cover on all segments ranged from 55 to 79%, with no differences between seeding rates. Mean runoff was significantly higher on the northwest-facing segments than on the southeast-facing segments, but runoff volumes did not decrease on either aspect in concert with loadings or concentrations. Higher runoff on the northwest-facing segments may have been due to clay-skinned peds in subsurface soil that limited vertical drainage. Even with a heavy straw mulch cover on the right-of-way, the timing of the highest sediment losses immediately following pipeline construction suggests that implementation of additional surface-protection best management practices could be beneficial until vegetation is reestablished.
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Notes
The use of trade or firm names in this publication is for reader information and does not imply endorsement by the US Department of Agriculture of any product or service.
References
Agassi, M., & Ben-Hur, M. (1991). Effect of slope length, aspect, and phosphogypsum on runoff and erosion from steep slopes. Australian Journal of Soil Research, 29(2), 197–207.
Agassi, M., & Ben-Hur, M. (1992). Stabilizing steep slopes with soil conditioners and plants. Soil Technology, 5(3), 249–256.
Ajwa, H. A., & Trout, T. J. (2006). Polyacrylamide and water quality effects on infiltration in sandy loam soils. Soil Society of America Journal, 70, 643–650.
APHA, AWWA, & WPCF. (1985). In A. E. Greenberg, R. R. Trussell, L. S. Clesceri, & M. A. H. Franson (Eds.), Standard methods for the examination of water and wastewater (16th ed.). Washington, DC: American Public Health Association.
Bethlahmy, N., & Kidd Jr., W. J. (1966). Controlling soil movement from steep road fills. Research note INT-45. Ogden: USDA Forest Service, Intermountain Forest and Range Experiment Station.
Bhatt, R., & Khera, K. L. (2006). Effect of tillage and mode of straw mulch application on soil erosion in the submontaneous tract of Punjab, India. Soil and Tillage Research, 88, 107–115.
Blais, D. P., & Simpson Jr., D. L. (1997). The effects of a buried natural gas pipeline on water quality, stream habitat, and biotic populations within high quality cold water streams in upstate New York. In J. R. Williams, J. W. Goodrich-Mahoney, J. R. Wisniewski, & J. Wisniewski (Eds.), Sixth International Symposium on Environmental Concerns in Rights-Of-Way Management (pp. 433–442). New York: Elsevier Science.
Bold, K. C., Wood, F., Edwards, P. J., Williard, K. W. J., & Schoonover, J. E. (2010). Using photographic image analysis to assess ground cover: a case study of forest road cutbanks. Environmental Monitoring and Assessment, 163, 685–698.
Brown, V. A., McDonnell, J. J., Burns, D. A., & Kendall, C. (1999). The role of event water, a rapid shallow component, and catchment size in summer stormflow. Journal of Hydrology, 217, 171–190.
Bryan, R. B., & Poesen, J. (1989). Laboratory experiments on the influence of slope length on runoff, percolation and rill development. Earth Surface Processes and Landforms, 14(3), 211–231.
Carroll, C., Merton, L., & Burger, P. (2000). Impact of vegetative cover and slope on runoff, erosion, and water quality for field plots on a range of soil and spoil materials on central Queensland coal mines. Australian Journal of Soil Research, 38(2), 313–327.
Castro, J. M., MacDonald, A., Lynch, E., & Thorne, C. R. (2015). Risk-based approach to designing and reviewing pipeline stream crossings to minimize impacts to aquatic habitats and species. River Research and Applications, 31(6), 767–783.
Cerdà, A. (2007). Soil water erosion on road embankments in eastern Spain. Science of the Total Environment, 378(1–2), 151–155.
Chaplot, V., & LeBissonnais, Y. (2000). Field measurements of interrill erosion under different slopes and plot sizes. Earth Surface Processes and Landforms, 25(2), 145–153.
Chaudhari, K., & Flanagan, D. C. (1998). Polyacrylamide effect on sediment yield, runoff, and seedling emergence on a steep slope. In Proceedings, ASAE Annual International Meeting, Paper 98–2155. St. Joseph: American Society of Agricultural Engineers.
Croke, J., & Mockler, S. (2001). Gully initiation and road-to-stream linkage in a forested catchment, southeastern Australia. Earth Surface Processes and Landforms, 26, 205–217.
Davidson, R. A., Davidson, C. F., & Roa-Espinosa, A. (2009). Linear anionic polyacrylamide as an effective post-fire soil treatment: understanding the chemistry and physical science. Journal of Soil and Water Conservation, 64(4), 243–252.
Döring, T. F., Brandt, M., Heß, J., Finckh, M. R., & Saucke, H. (2005). Effects of straw mulch on soil nitrate dynamics, weeds, yield and soil erosion in organically grown potatoes. Field Crops Research, 94(2–3), 238–249.
Dunne, T., & Black, R. D. (1970). An experimental investigation of runoff production in permeable soils. Water Resources Research, 6(2), 478–490.
Dyrness, C. T. (1975). Grass-legume mixtures for erosion control along forest roads in western Oregon. Journal of Soil and Water Conservation, 30(4), 169–173.
Edwards, P. J., Wood, F., & Quinlivan, R. L. (2016). Effectiveness of best management practices that have application to forest roads: A literature synthesis. General Technical Report NRS-163. Newtown Square: USDA, Forest Service, Northern Research Station.
Elwell, H. A., & Stocking, M. A. (1976). Vegetal cover to estimate soil erosion hazard in Rhodesia. Geoderma, 15(1), 61–70.
Energy Information Administration, Office of Energy Analysis. (2016). International Energy Outlook 2016: with projections to 2040, Chapter 3: Natural Gas. Report No. DOE/EIA-04884(2016) (pp. 37–60). Washington, DC: U.S. Energy Information Administration, Department of Energy. https://www.eia.gov/forecasts/ieo/pdf/0484(2016).pdf. Accessed Oct 2016.
Energy Information Administration, Office of Oil and Gas. (2009). Expansion of the U.S. natural gas pipeline network: additions in 2008 and projections through 2011. Resource document. Energy Information Administration, Department of Energy. http://www.eia.gov/naturalgas/archive/pipelinenetwork.pdf. Accessed Oct 2013.
Flanagan, D.C. & Chaudhari, K. (1999). Erosion control with polyacrylamide on steep slopes. Proceedings, ASAE Annual International Meeting, Paper 99–2011. St. Joseph, MI: American Society of Agricultural Engineers.
Foltz, R. B., & Dooley, J. H. (2003). Comparison of erosion reduction between wood strands and agricultural straw. Transactions of the American Society of Agricultural Engineers, 46(5), 1389–1396.
Fox, D., & Bryan, R. B. (1992). Influence of a polyacrylamide soil conditioner on runoff generation and soil erosion: field tests in Baringo District, Kenya. Soil Technology, 5(2), 101–119.
Gray, D. H. (1995). Influence of vegetation on the stability of slopes. In D. H. Barker (Ed.), Vegetation and slopes: stabilisation, protection, and ecology, proceedings of the International Conference held at the University Museum (pp. 2–25). London: Thomas Telford Limited.
Green, V. S., & Stott, D. E. (2001). Polyacrylamide: A review of the use, effectiveness, and cost of a soil erosion control amendment. In D. E. Stott, R. H. Mohtar, & G. C. Steinhardt (Eds.), Sustaining the global farm: 10th International Soil Conservation Organization meeting (pp. 384–389). Purdue: Purdue University.
Green, V. S., Stott, D. E., Norton, L. D., & Graveel, J. G. (2000). Polyacrylamide molecular weight and charge effects on infiltration under simulated rainfall. Soil Science of America Journal, 64(5), 1786–1791.
Hann, M. J., & Morgan, R. P. C. (2006). Evaluating erosion control measures for biorestoration between the time of soil reinstatement and vegetation establishment. Earth Surface Processes and Landforms, 31, 589–597.
Harrison, B. (2011). Erosion from a cross country gas pipeline in the central Appalachians. M.S. thesis. Department of Forestry. Carbondale, IL: Southern Illinois University.
Hewlett, J. D., & Troendle, C. A. (1975). Non-point and diffused water sources: a variable source area problem. In Proceedings: Symposium on Watershed Management (pp. 21–46). New York: American Society of Civil Engineers.
Holz, D. (2009). Factors affecting erosion on a natural gas pipeline in the central Appalachians. M.S. thesis. Department of Forestry. Carbondale, IL: Southern Illinois University.
Holz, D., Williard, K. W. J., Edwards, P. J., & Schoonover, J. E. (2015). Soil erosion in humid regions: a review. Journal of Contemporary Water Research & Education, 154, 48–59.
Jennings, G. D., & Jarrett, A. R. (1985). Laboratory evaluation of mulches in reducing erosion. Transactions of the American Society of Agricultural Engineers, 28(5), 1466–1470.
Ketcheson, G. L., & Megahan, W. F. (1996). Sediment production and downslope sediment transport from forest roads in granitic watersheds. Research paper INT-RP-486. Ogden: USDA Forest Service, Intermountain Research Station.
Kochenderfer, J. N., & Helvey, J. D. (1987). Using gravel to reduce soil losses from minimum-standard forest roads. Journal of Soil and Water Conservation, 42(1), 46–50.
Lattanzi, A. R., Meyer, L. D., & Baumgardner, M. F. (1974). Influence of mulch rate and slope steepness on interrill erosion. Soil Science Society of America Proceedings, 38(6), 946–950.
Lévesque, L. M., & Dubé, M. G. (2007). Review of the effects of in-stream pipeline crossing construction on aquatic ecosystems and examination of Canadian methodologies for impact assessment. Environmental Monitoring and Assessment, 132, 395–409.
Levy, G. J., & Agassi, M. (1995). Polymer molecular weight and degree of drying effects on infiltration and erosion of three different soils. Australian Journal of Soil Research, 33(6), 1007–1018.
McDonnell, I. F., Owens, J. F., & Stewart, M. K. (1991). A case study of shallow flow paths in a steep zero-order basin. Water Resources Bulletin, 27, 679–685.
McLaughlin, R. A., & Jennings, G. E. (2007). Minimizing water quality impacts of road construction projects. Final Report to the North Carolina Department of Transportation, Report No. FHWA/NC/2006–21.
Megahan, W. F., Wilson, M., & Monsen, S. B. (2001). Sediment production from granitic cutslopes on forest roads in Idaho, USA. Earth Surface Processes and Landforms, 26(2), 153–163.
Meyer, L. D., & Mannering, J. V. (1963). Crop residues as surface mulches for controlling erosion on sloping land under intensive cropping. Transactions of the American Society of Agricultural Engineers, 6(4), 322–323,327.
Meyer, L. D., Johnson, C. B., & Foster, G. R. (1972). Stone and woodchip mulches for erosion control on construction sites. Journal of Soil and Water Conservation, 27(6), 264–269.
Moreno-de las Heras, M., Merino-Martín, L., & Nicolau, J. M. (2009). Effect of vegetation cover on the hydrology of reclaimed mining soils under Mediterranean-continental climate. Catena, 77(1), 39–47.
Morgan, R. P. C., & Hann, M. J. (2005). Design of diverter berms for soil erosion control and biorestoration along pipeline rights-of-way. Soil Use and Management, 21, 306–311.
Morgan, R. P. C., Mirtskhoulava, T. E., Nadirashvili, V., Hann, M. J., & Gasca, A. H. (2003). Spacing of berms for erosion control along pipeline rights-of-way. Biosystems Engineering, 85(2), 249–259.
Moss, A. J. (1991). Rain-impact soil crust. I: formation on a granite-derived soil. Australian Journal of Soil Research, 29(2), 271–289.
Nelson, J. K. (2006). Revegetation of the Rocky Flats, Colorado site. In W. R. Keammerer (Ed.), Proceedings High Altitude Revegetation Workshop no. 17 (pp. 229–234). Fort Collins: Colorado Water Resources Research Institute.
Nelson, J. K. (2012). Riparian and upland restoration at the U.S. Department of Energy Rocky Flats, Colorado, site–12360. In WM2012 Conference, improving the future in waste management. Phoenix, AZ: WM Symposium, Inc.
Orr, H. K. (1970). Runoff and erosion control by seeded and native vegetation on a forest burn: Black Hills, South Dakota. Research paper RM-60. Fort Collins: USDA Forest Service, Rocky Mountain Forest and Range Experiment Station.
Patric, J. H. (1976). Soil erosion in the eastern forest. Journal of Forestry, 74(10), 671–677.
Petersen, A. L., Thompson, A. M., Baxter, C. A., Norman, J. M., & Roa-Espinosa, A. (2007). A new polyacrylamide (PAM) formulation for reducing erosion and phosphorus loss in rainfed agriculture. Transactions of the American Society of Agricultural and Biological Engineers, 50(6), 2091–2101.
Pierre, J. P., Abolt, C. J., & Young, M. H. (2015). Impacts from above-ground activities in the Eagle Ford Shale play on landscapes and hydrologic flows, La Salle County, Texas. Environmental Management, 55, 1262–1275.
Quansah, C. (1981). The effect of soil type, slope, rain intensity and their interactions on splash detachment and transport. European Journal of Soil Science, 32(2), 215–224.
Quinton, J. N., Edwards, G. M., & Morgan, R. P. C. (1997). The influence of vegetation species and plant properties on runoff and soil erosion: results from a rainfall simulation study in south east Spain. Soil Use and Management, 13(3), 143–148.
Reid, S. M., & Anderson, P. G. (1999). Effects of sediment released during open-cut pipeline water crossings. Canadian Water Resources Journal, 24(3), 235–251.
Reid, S., & Anderson, P. G. (2000). Evaluation of isolated watercourse crossings during winter construction along the Alliance Pipeline in northern Alberta. In J. W. Goodrich-Mahoney, D. Mutrie, & C. Guild (Eds.), Proceedings of the 7th International Symposium on Environmental Concerns in Rights-Of-Way Management (pp. 735–742). Amsterdam: Elsevier Science.
Reid, S. M., Stoklosar, S., Metikosh, S., & Evans, J. (2002). Effectiveness of isolated pipe crossing techniques to mitigate sediment impacts on brook trout streams. Water Quality Research Journal Canada, 37(2), 473–488.
Roose, E. J. (1975). Natural mulch or chemical conditioner for reducing soil erosion in humid tropical areas. In W. R. Gardner & W. C. Moldenhauer (Eds.), Soil conditioners, Soil Science Society of America Special Publication 7 (pp. 131–138). Madison: Soil Science Society of America.
SAS Institute. (1998). SAS/STAT user’s guide, release 9.1 edition. Cary: SAS Institute Inc.
Shainberg, I., Warrington, D. N., & Rengasamy, P. (1990). Water quality and PAM interactions in reducing surface sealing. Soil Science, 149(5), 301–307.
Smith, C. E. (2013). US pipeline operators sink revenue growth into expansion. Oil & Gas Journal. http://www.ogj.com/articles/print/volume-111/issue-9/special-report-pipeline-economics/us-pipeline-operators-sink-revenue-growth-into-expansion.html. Accessed 25 Sept 2013.
Sojka, R. E., & Lentz, R. (1994). Time for yet another look at soil conditioners. Soil Science, 158(4), 233–234.
Sojka, R. E., & Lentz, R. (1996a). Polyacrylamide for furrow-irrigation erosion control. Irrigation Journal, 46(1), 8–11.
Sojka, R. E., & Lentz, R. D. (1996b). A PAM primer: a brief history of PAM and PAM-related issues. In Proceedings, managing irrigation-induced erosion and infiltration with polyacrylamide. Miscellaneous publication No. 101–96. Moscow, ID: University of Idaho.
Stedman, J. T. (2008). To-stream sediment delivery and associated particle size distributions in unmanaged and managed forested watersheds. M.S. thesis. Department of Forestry. Carbondale, IL: Southern Illinois University.
Swistock, B. R., Edwards, P. J., Wood, F., & DeWalle, D. R. (1997). Comparison of methods for calculating annual solute exports from six forested Appalachian watersheds. Hydrological Processes, 11, 655–669.
Texas Department of Transportation. (2014). General product material descriptions. TxDOT/TTI Sedimentation and Erosion Control (SEC) Laboratory, Final Performance Analysis – July 2014. 24 p. https://ftp.dot.state.tx.us/pub/txdot-info/mnt/erosion/product_evaluation/description.pdf. Accessed 30 March 2017.
Trout, T.J., & Ajwa, H. (2001). Polyacrylamide effects on infiltration in San Joaquin Valley sandy loam soils. In Proceedings, ASAE Annual International Meeting, Paper 012259. St. Joseph, MI: American Society of Agricultural Engineers.
United States Department of Transportation. (2015). National Transportation Statistics, Chapter 1—the transportation system, Table 1–10 – U.S. oil and gas pipeline mileage (updated April 2015). Resource document. Office of the Assistant Secretary for Research and Technology, Bureau of Transportation Statistics. http://www.rita.dot.gov/bts/sites/rita.dot.gov.bts/files/publications/national_transportation_statistics/html/table_01_10.html. Accessed 11 Jan 2016.
Wade, C. R. (2010). Evaluation of best management practices for bladed skid trail erosion control and determination of erosion model accuracy and applicability. M.S. thesis. Blacksburg, VA: Virginia Polytechnic Institute and State University.
Wallace, G. A., & Wallace, A. (1986). Control of soil erosion by polymeric soil conditioners. Soil Science, 141(5), 363–367.
Wemple, B. C., Jones, J. A., & Grant, G. E. (1996). Channel network extension by logging roads in two basins, western Cascades, Oregon. Water Resources Bulletin, 32(6), 1195–1207.
Winning, H. K., & Hann, M. J. (2014). Modelling soil erosion risk for pipelines using remote sensed data. Biosystems Engineering, 127, 135–143.
Woo, M., Fang, G., & diCenzo, P. (1997). The role of vegetation in the retardation of rill erosion. Catena, 29(2), 145–159.
Young, R. A., & Wiersma, J. L. (1973). The role of rainfall impact in soil detachment and transport. Water Resources Research, 9(6), 1629–1636.
Yu, J., Lei, T., Shainberg, I., Mamedov, A. I., & Levy, G. J. (2003). Infiltration and erosion in soils treated with dry PAM and gypsum. Soil Science Society of America Journal, 67, 630–636.
Acknowledgments
The authors thank the USDA Forest Service, Monongahela National Forest, who provided funding and assistance for this administrative study. We particularly thank Linda Tracy, Forest Geologist (retired) for her assistance with logistics and Stephanie Connolly, Forest Soil Scientist, for describing the soils on the pipeline right-of-way. Also, thanks go to Greg Evans for his contributions to equipment installation and maintenance, sample collection, and laboratory analyses, and Frederica Wood for surveying, ground cover photography, and image analysis.
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Descriptions of soil pits 1-3 adjacent to the FEF pipeline ROW, made by Stephanie J. Connolly, Monongahela National Forest Soil Scientist. Depth units for all three pits are cm. Blank fields indicate data that were not recorded at the time the soil was described.
Descriptions of soil pits 1-3 adjacent to the FEF pipeline ROW, made by Stephanie J. Connolly, Monongahela National Forest Soil Scientist. Depth units for all three pits are cm. Blank fields indicate data that were not recorded at the time the soil was described.
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Edwards, P.J., Harrison, B.M., Williard, K.W. et al. Erosion from a Cross-Country Natural Gas Pipeline Corridor: The Critical First Year. Water Air Soil Pollut 228, 232 (2017). https://doi.org/10.1007/s11270-017-3374-9
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DOI: https://doi.org/10.1007/s11270-017-3374-9