Research article

The technical challenges and outcomes of ground-penetrating radar: A site-specific example from Joggins, Nova Scotia

  • Received: 15 December 2020 Accepted: 07 January 2021 Published: 18 January 2021
  • The Carboniferous Joggins Formation is known for its complete succession of fossil-rich, coal-bearing strata, deposited in a fluvial meanderbelt depositional setting. Hence, the Joggins Formation outcrop is an excellent analogue for studying the 2D geological complexities associated with meanderbelt systems. In this research, a conventional ground-penetrating radar system was tested with the intent of imaging near-surface, dipping, strata of the Joggins Formation (potentially with subsequent repeats as annual erosion provides new visual calibrations). The survey was unsuccessful in its primary goal, and for future reference we document the reasons here. However, the overlying near-surface angular unconformity was successfully imaged enabling mapping of the approximately 8 m of overlying glacial till. A successful outcome would have allowed observations from the 2D outcrop to be extended into 3D space and perhaps lead to an increased understanding of the small (e.g., bedform baffles and barriers) and large (e.g., channel bodies) scale architectural elements, meanderbelt geometry, and aspect ratios. The study comprises a 42-line, 3.46 km ground-penetrating radar survey using a Sensors and Software pulseEKKO Pro SmartCart system. It was combined with a real-time kinematic differential global positioning system for the georeferencing of survey lines. The 50 MHz antenna frequency, with a 1 m separation, was chosen to maximize the depth of penetration, while still maintaining a reasonable resolution. The results show that many of the lines are contaminated with diffraction hyperbolae, possibly caused from buried objects near or under the survey lines or surface objects near the survey lines. A total of thirteen unique radar reflectors are described and interpreted from this work. The thick clay-rich soil overlying the Joggins Formation probably contributed to significant signal attenuation and the nature of the Carboniferous strata (dip of the beds, pinching and swelling of the beds, bed thickness, etc.) also contributed to imaging difficulties.

    Citation: Trevor B. Kelly, Grant D. Wach, Darragh E. O'Connor. The technical challenges and outcomes of ground-penetrating radar: A site-specific example from Joggins, Nova Scotia[J]. AIMS Geosciences, 2021, 7(1): 22-55. doi: 10.3934/geosci.2021002

    Related Papers:

  • The Carboniferous Joggins Formation is known for its complete succession of fossil-rich, coal-bearing strata, deposited in a fluvial meanderbelt depositional setting. Hence, the Joggins Formation outcrop is an excellent analogue for studying the 2D geological complexities associated with meanderbelt systems. In this research, a conventional ground-penetrating radar system was tested with the intent of imaging near-surface, dipping, strata of the Joggins Formation (potentially with subsequent repeats as annual erosion provides new visual calibrations). The survey was unsuccessful in its primary goal, and for future reference we document the reasons here. However, the overlying near-surface angular unconformity was successfully imaged enabling mapping of the approximately 8 m of overlying glacial till. A successful outcome would have allowed observations from the 2D outcrop to be extended into 3D space and perhaps lead to an increased understanding of the small (e.g., bedform baffles and barriers) and large (e.g., channel bodies) scale architectural elements, meanderbelt geometry, and aspect ratios. The study comprises a 42-line, 3.46 km ground-penetrating radar survey using a Sensors and Software pulseEKKO Pro SmartCart system. It was combined with a real-time kinematic differential global positioning system for the georeferencing of survey lines. The 50 MHz antenna frequency, with a 1 m separation, was chosen to maximize the depth of penetration, while still maintaining a reasonable resolution. The results show that many of the lines are contaminated with diffraction hyperbolae, possibly caused from buried objects near or under the survey lines or surface objects near the survey lines. A total of thirteen unique radar reflectors are described and interpreted from this work. The thick clay-rich soil overlying the Joggins Formation probably contributed to significant signal attenuation and the nature of the Carboniferous strata (dip of the beds, pinching and swelling of the beds, bed thickness, etc.) also contributed to imaging difficulties.


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    [1] McMechan GA, Gaynor GC, Szerbiak RB (1997) Use of ground-penetrating radar for 3-D sedimentological characterization of clastic reservoir analogs. Geophysics 62: 786-796. doi: 10.1190/1.1444188
    [2] Knight R, Tercier P, Jol H (1997) The role of ground penetrating radar and geostatistics in reservoir description. Leading Edge 16: 1576-1584. doi: 10.1190/1.1437526
    [3] Møller I, Anthony D (2003) A GPR study of sedimentary structures within a transgressive coastal barrier along the Danish North Sea coast. Geol Soc London Spec Publ 211: 55-65. doi: 10.1144/GSL.SP.2001.211.01.05
    [4] Lanzarone P, Garrison E, Bobe R, et al. (2016) Examining Fluvial Stratigraphic Architecture Using Ground-Penetrating Radar at the Fanta Stream Fossil and Archaeological Site, Central Ethiopia. Geoarchaeology 31: 577-591. doi: 10.1002/gea.21584
    [5] Kostic B, Aigner T (2007) Sedimentary architecture and 3D ground-penetrating radar analysis of gravelly meandering river deposits (Neckar Valley, SW Germany). Sedimentology 54: 789-808. doi: 10.1111/j.1365-3091.2007.00860.x
    [6] Rey J, Martinez J, Hidalgo MC (2013) Investigating fluvial features with electrical resistivity imaging and ground-penetrating radar: The Guadalquivir River terrace (Jaen, Southern Spain). Sediment Geol 295: 27-37. doi: 10.1016/j.sedgeo.2013.07.003
    [7] Smith DG, Jol HM (1992) Ground-penetrating radar investigation of a Lake Bonneville delta, Provo level, Brigham City, Utah. Geology 20: 1-4. doi: 10.1130/0091-7613(1992)020<1083:GPRIOA>2.3.CO;2
    [8] Barboza EG, Rosa MLCC, Dillenburg SR, et al. (2014) Stratigraphic analysis applied on the recognition of the interface between marine and fluvial depositional systems. J Coastal Res 70: 687-692. doi: 10.2112/SI70-116.1
    [9] Leandro CG, Barboza EG, Caron F, et al. (2019) GPR trace analysis for coastal depositional environments of southern Brazil. J Appl Geophys 162: 1-12. doi: 10.1016/j.jappgeo.2019.01.002
    [10] Dillenburg SR, Barboza EG, Rosa MLCC, et al. (2017) The complex prograded Cassino barrier in southern Brazil: Geological and morphological evolution and records of climatic, oceanographic and sea-level changes in the last 7-6 ka. Mar Geol 390: 106-119. doi: 10.1016/j.margeo.2017.06.007
    [11] Dillenburg SR, Hesp PA, Keane R, et al. (2020) Geochronology and evolution of a complex barrier, Younghusband Peninsula, South Australia. Geomorphology 354: 107044. doi: 10.1016/j.geomorph.2020.107044
    [12] Neal A (2004) Ground-penetrating radar and its use in sedimentology: principles, problems and progress. Earth Sci Rev 66: 261-330. doi: 10.1016/j.earscirev.2004.01.004
    [13] Neal A, Roberts CL (2000) Applications of ground-penetrating radar (GPR) to sedimentological, geomorphological and geoarchaeological studies in coastal environments. In Pye K, Allen JRL, editor. Coastal and Estuarine Environments: Sedimentology, Geomorphology and Geoarchaeology, 175: 139-171.
    [14] Jol HM (2009) Ground Penetrating Radar Theory and Applications. In Jol HM, editor. Oxford: Elsevier Science, 545.
    [15] Jol HM, Smith DG (1991) Ground penetrating radar of northern lacustrine deltas. Can J Earth Sci 28: 1939-1947. doi: 10.1139/e91-175
    [16] Beres Jr M, Haeni FP (1991) Application of ground-penetrating-radar Methods in Hydrogeologie Studies. Groundwater 29: 375-386. doi: 10.1111/j.1745-6584.1991.tb00528.x
    [17] Van Sickle J (2015) GPS for Land Surveyors. CRC Press, 368.
    [18] Gibling MR (2006) Width and thickness of fluvial channel bodies and valley fills in the geological record: A literature compilation and classification. J Sediment Res 76: 731-770. doi: 10.2110/jsr.2006.060
    [19] Calder JH, Boon J (2007) Joggins Fossil Cliffs: Property Nominated for Inscription on the World Heritage List. Halifax, NS: Nova Scotia Department of Natural Resources, Mineral Resources Branch. Open File Map ME 2007-2001.
    [20] Calder JH, Gibling MR, Scott AC, et al. (2006) A fossil lycopsid forest succession in the classic Joggins section of Nova Scotia: paleoecology of a disturbance-prone Pennsylvanian wetland. Geol Soc Am 399: 169.
    [21] Davies SJ, Gibling M, Rygel MC, et al. (2005) The Pennsylvanian Joggins Formation of Nova Scotia: sedimentological log and stratigraphic framework of the historic fossil cliffs. Atl Geol 41: 115-142.
    [22] Davies SJ, Gibling MR (2003) Architecture of coastal and alluvial deposits in an extensional basin: the Carboniferous Joggins Formation of eastern Canada. Sedimentology 50: 415-439. doi: 10.1046/j.1365-3091.2003.00553.x
    [23] Rygel MC, Gibling MR, Calder JH (2004) Vegetation-induced sedimentary structures from fossil forests in the Pennsylvanian Joggins Formation, Nova Scotia. Sedimentology 51: 531-552. doi: 10.1111/j.1365-3091.2004.00635.x
    [24] Grey M, Finkel ZV (2011) The Joggins Fossil Cliffs UNESCO World Heritage site: a review of recent research. Atl Geol 47: 185-200. doi: 10.4138/atlgeol.2011.009
    [25] Rygel MC, Gibling MR (2006) Natural geomorphic variability recorded in a high-accommodation setting: fluvial architecture of the Pennsylvanian Joggins Formation of Atlantic Canada. J Sediment Res 76: 1230-1251. doi: 10.2110/jsr.2006.100
    [26] Waldron JWF, Rygel MC (2005) Role of evaporite withdrawal in the preservation of a unique coal-bearing succession: Pennsylvanian Joggins Formation, Nova Scotia. Geology 33: 337-340. doi: 10.1130/G21302.1
    [27] Carpenter DK, Falcon-Lang HJ, Benton MJ, et al. (2015) Early Pennsylvanian (Langsettian) fish assemblages from the Joggins Formation, Canada, and their implications for palaeoecology and palaeogeography. Palaeontology 58: 661-690. doi: 10.1111/pala.12164
    [28] Archer AW, Calder JH, Gibling MR, et al. (1995) Invertebrate trace fossils and agglutinated foraminifera as indicators of marine influence within the classic Carboniferous section at Joggins, Nova Scotia, Canada. Can J Earth Sci 32: 2027-2039. doi: 10.1139/e95-156
    [29] Reisz R, Modesto SP (1996) Archerpeton anthracos from the Joggins Formation of Nova Scotia: a microsaur, not a reptile. Can J Earth Sci 33: 703-709. doi: 10.1139/e96-053
    [30] Tibert NE, Dewey CP (2006) Velatomorpha, a new healdioidean ostracode genus from the early Pennsylvanian Joggins Formation, Nova Scotia, Canada. Micropaleontology 52: 51-66. doi: 10.2113/gsmicropal.52.1.51
    [31] Carroll RL (1967) Labyrinthodonts from the Joggins Formation. J Paleontol 41: 111-142.
    [32] Brand U (1994) Continental hydrology and climatology of the Carboniferous Joggins Formation (lower Cumberland Group) at Joggins, Nova Scotia: evidence from the geochemistry of bivalves. Palaeogeogr Palaeoclimatol Palaeoecol 106: 307-321. doi: 10.1016/0031-0182(94)90016-7
    [33] UNESCO (2008) World Heritage List-Joggins Fossil Cliffs.
    [34] Falcon-Lang HJ (2009) Earliest history of coal mining and grindstone quarrying at Joggins, Nova Scotia, and its implications for the meaning of the place name "Joggins". Atl Geol 45: 1-20. doi: 10.4138/atlgeol.2009.001
    [35] Rust BR, Gibling MR, Legun AS (1985) Coal deposition in an anastomosing-fluvial system: the Pennsylvanian Cumberland Group south of Joggins, Nova Scotia, Canada. In Rahmani RA, Flores RM, editor. Sedimentology of Coal and Coal-Bearing Sequences, 105-120.
    [36] Quann SL, Young AB, Laroque CP, et al. (2010) Dendrochronological dating of coal mine workings at the Joggins Fossil Cliffs, Nova Scotia, Canada.
    [37] Google Maps (2020) Google basemap of Joggins Area. Google.
    [38] Nowland JL, MacDougall JI (1973) Nova Scotia Soil Survey-Soils of Cumberland County Nova Scotia. Canada Department of Agriculture, editor. Ottawa: D.W. Friesen and Sons Ltd., 154.
    [39] Keys K, Neily P, Quigley E (2010) Forest Ecosystem Classification for Nova Scotia (Part Ⅱ: Soil Types). Resources NSDoN, editor. Halifax, Nova Scotia: Nova Scotia Department of Natural Resources, 121.
    [40] Prothero DR, Schwab F (2003) Sedimentary Geology: An Introduction to Sedimentary Rocks and Stratigraphy. Freeman & Company, W & H. 600.
    [41] Stea RR, Finck PW (1986) Surficial Geology, Chigneto Peninsula, Nova Scotia (Sheet 9). Geological Survey of Canada, Map 1630A.
    [42] Ryan RJ, Calder JH, Donohoe Jr. HV, et al. (1987) Late Paleozoic Sedimentation and Basin Development Adjacent to the Cobequid Highlands Massif, Eastern Canada. In: Beaumont C, Tankard AJ, editors. Memoir 12-Sedimentary basins and basin-forming mechanisms. Halifax: Atlantic Geoscience Society, 311-317.
    [43] RPS Energy (2010) Screening of Potential CO2 Storage Sites Onshore Nova Scotia. Carbon Capture and Storage Research Consortium of Nova Scotia.
    [44] Ryan RJ, Boehner RC (1994) Geology of the Cumberland Basin, Cumberland, Colchester and Pictou Counties, Nova Scotia. Mines and Energy Branch. Halifax: Department of Natural Resources.
    [45] Browne GH, Plint AG (1994) Alternating braidplain and lacustrine deposition in a strike-slip setting: The Pennsylvanian Boss Point Formation of the Cumberland Basin, Maritime Canada. J Sediment Res 64: 40-59. doi: 10.1306/D4267E92-2B26-11D7-8648000102C1865D
    [46] Martel TA (1987) Seismic Stratigraphy and Hydrocarbon Potential of the Strike-Slip Sackville Sub-Basin, New Brunswick. In: Beaumont C, Tankard AJ, editors. Memoir 12-Sedimentary basins and basin-forming mechanisms. Halifax: Atlantic Geoscience Society, 319-334.
    [47] Allen JP, Fielding CR, Rygel MC, et al. (2013) Deconvolving Signals of Tectonic and Climatic Controls From Continental Basins: An Example From the Late Paleozoic Cumberland Basin, Atlantic Canada. J Sediment Res 83: 847-872. doi: 10.2110/jsr.2013.58
    [48] Kelly TB, Wach GD (2020) Analysis of factors influencing the interpretation of a digitally examined fluvial meanderbelt system: Joggins Formation, Nova Scotia. Can J Earth Sci 57: 524-541. doi: 10.1139/cjes-2018-0263
    [49] Rygel MC (2005) Alluvial sedimentology and basin analysis of carboniferous strata near Joggins, Nova Scotia, Atlantic Canada. Halifax, NS: Dalhousie University.
    [50] Gibling MR, Calder JH, Ryan R, et al. (1992) Late Carboniferous and early Permian drainage patterns in Atlantic Canada. Can J Earth Sci 29: 338-352. doi: 10.1139/e92-030
    [51] Szymczyk M, Szymczyk P (2013) Preprocessing of GPR data. Image Process Commun 18: 83-90. doi: 10.2478/v10248-012-0082-3
    [52] Dojack L (2012) Ground Penetrating Radar Theory, Data Collection, Processing, and Interpretation: A Guide for Archaeologist. University of British Columbia: University of British Columbia, Laboratory of Archaeology, 94.
    [53] Annan AP (2003) Ground Penetrating Radar Principles, Procedures & Applications. Sensors and Software Inc.
    [54] Annan AP (1999) Practical Processing of GPR Data. Sensors and Software Inc., 1-18.
    [55] Google (2013) Streetview. Google Inc.
    [56] Ékes C, Friele P (2003) Sedimentary architecture and post-glacial evolution of Cheekye fan, southwestern British Columbia, Canada. Geol Soc London Spec Publ 211: 87-98. doi: 10.1144/GSL.SP.2001.211.01.08
    [57] Heteren SV, Fitzgerald DM, Mckinlay PA, et al. (1998) Radar facies of paraglacial barrier systems: coastal New England, USA. Sedimentology 45: 181-200. doi: 10.1046/j.1365-3091.1998.00150.x
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