Gas hydrates (GHs) are a prominent subsurface feature on the Canadian Arctic continental margin. They occur both onshore and offshore, although they formed generally terrestrially, during the last glacial sea level low-stand, both in a region that was persistently glaciated (Queen Elizabeth Islands Group, Canadian Arctic Archipelago (QEIG)), and in a region that was not persistently glaciated (Mackenzie Delta-Beaufort Sea (MD-BS)). Parts of both regions were transgressed in the Holocene. We study the dynamic permafrost and GH history in both regions using a numerical model to illustrate how changes in setting and environment, especially periodic glacial ice cover, affected GH stability. MD-BS models represent the Mallik wellsite and these models successfully match current permafrost and GH bases observed in the well-studied Mallik wells. The MD-BS models show clearly that GHs have persisted through interglacial episodes. Lower surface temperatures in the more northerly QEIG result in an earlier appearance of GH stability that persists through glacial-interglacial intervals, although the base of GH base stability varies up to 0.2?km during the 100?ka cycles. Because of the persistent glacial ice cover QEIG models illustrate pressure effects attributed to regional ice sheet loading on the bases of both permafrost and GHs since 0.9?MYBP. QEIG model permafrost and GH depths are 572?m and 1072?m, respectively, which is like that observed commonly on well logs in the QEIG. In order to match the observed GH bases in the QEIG it is necessary to introduce ice buildup and thaw gradually during the glacials and interglacials. QEIG sea level rose 100–120?m about 10?ka ago following the most recent glaciation. Shorelines have risen subsequently due to isostatic glacial unloading. Detailed recent history modeling in QEIG coastal regions, where surface temperatures have changed from near zero in the offshore to ?20°C in the onshore setting results in a model GH stability base, that is, <0.5?km. These coastal model results are significantly shallower than the inferred average GH base about 1?km in wells, Smith and Judge (1993). QEIG interisland channels are generally shallow and much of the previous shoreline inundated by the Holocene transgression was above the glacial sea level low-stand during the last ice age, resulting in a QEIG setting somewhat analogous to the relict terrestrial GH now transgressed by the shallow Beaufort Sea. It is also possible that the marine conditions were present at emergent shorelines for a shorter time or that the pretransgression
References
[1]
J. A. Majorowicz and K. G. Osadetz, “Basic geological and geophysical controls bearing on gas hydrate distribution and volume in Canada,” AAPG Bulletin, vol. 85–87, pp. 1211–1230, 2001.
[2]
S. L. Smith and A. S. Judge, “Gas hydrate database for Canadian Arctic and selected east coast wells,” Geol. Surv. Canada Open File Report 2746, 120p., 1993.
[3]
S. R. Dallimore and T. S. Collett, Eds., “Scientific results from the Mallik 2002 gas hydrate production research well program, Mackenzie Delta, Northwest Territories, Canada,” Geol. Surv. Canada Bull.; 585, 140p. CD and Charts. 2005.
[4]
A. S. Dyke, “Last Glacial Maximum and deglaciation of Devon Island, Arctic Canada: support for an Innuitian ice sheet,” Quaternary Science Reviews, vol. 18, no. 3, pp. 393–420, 1999.
[5]
W. R. Peltier and J. T. Andrews, “Glacial-isostatic adjustment,1. The forward problem,” Geophysical Journal of the Royal Astronomical Society, vol. 46, pp. 605–646, 1976.
[6]
D. C. Mosher, K. Louden, J. Shimeld, and K. Osadetz, “Gas Hydrates Offshore Eastern Canada: Fuel for the Future?” in Proceedings of the Offshore Technology Conference, Houston, Tex, USA, May 2005.
[7]
J. A. Majorowicz and K. G. Osadetz, “Natural gas hydrate stability in the East Coast offshore-canada,” Natural Resources Research, vol. 12, no. 2, pp. 93–104, 2003.
[8]
M. Riedel, G. D. Spence, N. R. Chapman, and R. D. Hyndman, “Deep-sea gas hydrates on the northern Cascadia margin,” Leading Edge, vol. 20, no. 1, pp. 87–91, 2001.
[9]
K. G. Osadetz and Z. Chen, “A re-evaluation of Beaufort Sea-Mackenzie Delta basin gas hydrate resource potential: petroleum system approaches to non-conventional gas resource appraisal and geologically-sourced methane flux,” Bulletin of Canadian Petroleum Geology, vol. 58, no. 1, pp. 56–71, 2010.
[10]
Z. Chen and K. G. Osadetz, “Using discovery process models to improve petroleum resource assessments based on combinations of inferred accumulation reservoir parameters,” in Arctic Petroleum Geology, A. Spencer, A. Embry, D. Gautier, A. Stoupakova, and K. S?rensen, Eds., Memoir of the geological Society of London No. 35, 2011.
[11]
J. A. Majorowicz, P. K. Hannigan, and K. G. Osadetz, “Study of the natural gas hydrate "trap zone" and the methane hydrate potential in the Sverdrup Basin, Canada,” Natural Resources Research, vol. 11, no. 2, pp. 79–96, 2002.
[12]
K. G. Osadetz, G. R. Morrell, J. Dixon, et al., “Beaufort Sea-Mackenzie Delta Basin: a review of conventional and non-conventional (gas hydrate) petroleum reserves and undiscovered resources,” in Scientific Results from Mallik 2002 Gas Hydrate Production Research Well Program, Mackenzie Delta, Northwest Territories, Canada, S. R. Dallimore and T. S. Collett, Eds., Geological Survey of Canada, Bulletin, 2005.
[13]
J A Majorowicz, K. G. Osadetz, and J. Safanda, “Modeling temperature profiles considering the latent heat of physical-chemical reactions in permafrost and gas hydrates: the Mackenzie Delta terrestrial case,” in Proceedings of the 9th International Conference on Permafrost, D. L. Kane and K. M. Hinkel, Eds., pp. 1113–1118, 2008.
[14]
A. E. Taylor, “A constraint to the Wisconsinan glacial history, Canadian Arctic Archipelago,” Journal of Quaternary Science, vol. 3/1, pp. 15–18, 1988.
[15]
A. E. Taylor, S. R. Dallimore, R. Hyndman, and J. F. Wright, “Comparing the sensitivity of permafrost and marine gas hydrate to climate warming,” in Scientific Results from the Mallik 2002 Gas Hydrate Production Research Well Program, Mackenzie Delta, Northwest Territories, Canada, S. R. Dallimore and T. S. Collett, Eds., Geological Survey of Canada, Bulletin, 2005.
[16]
J. ?afanda, J. Szewczyk, and J. Majorowicz, “Geothermal evidence of very low glacial temperatures on a rim of the Fennoscandian ice sheet,” Geophysical Research Letters, vol. 31, no. 7, Article ID L07211, 4 pages, 2004.
[17]
Y. Galushkin, “Numerical simulation of permafrost evolution as a part of sedimentary basin modeling: permafrost in the Pliocene-Holocene climate history of the Urengoy field in the West Siberian basin,” Canadian Journal of Earth Sciences, vol. 34, no. 7, pp. 935–948, 1997.
[18]
D. W. Peaceman and H. H. Rachford, “The numerical solution of parabolic and elliptic differential equations,” Journal of the Society for Industrial and Applied Mathematics, vol. 3, no. 1, pp. 28–41, 1955.
[19]
H. S. Carslaw and J. C. Jaeger, Conduction of Heat in Solids, Oxford University Press, Oxford, UK, 2nd edition, 1959.
[20]
J. A. Majorowicz, F. W. Jones, and A. S. Judge, “Deep subpermafrost thermal regime in the Mackenzie Delta basin, northern Canada—analysis from petroleum bottom-hole temperature data,” Geophysics, vol. 55, no. 3, pp. 362–371, 1990.
[21]
A. E. Taylor, M. Burgess, Judge A. S., and V. S. Allen, Canadian Geothermal Data Collection-Northern Wells 1981, Geothermal Series Earth Physics Branch EMR,13, 1982.
[22]
J. F. Wright, F. M. Nixon, S. R. Dallimore, J. Henninges, and M. M. Cote, “Thermal conductivity of sediments within the gas hydrate bearing interval at the Mallik 5L-38 gas hydrate production well,” in Scientific Results from the Mallik 2002 Gas Hydrate Production Research Well Program, Mackenzie Delta, Northwest Territories, Canada, S. R. Dallimore and T. S. Collett, Eds., vol. 585, pp. 129–130, Geological Survey of Canada, Bulletin, 2005.
[23]
J. Henniges, E. Huenges, and H. Burkhard, “In situ thermal conductivity of gas hydrate bearing sediments of the Mallik 5L-38 well,” Journal of Geophysical Research, vol. 110, p. B11206, 2005.
[24]
E. D. Sloan, Clathrate Hydrates of Natural Gases, Marcel Dekker, New York, NY, USA, 2nd edition, 1998.
[25]
T. S. Collett, “Permafrost-associated gas hydrate accumulations,” in International Conference on Natural Gas Hydrates, E. D. Sloan, J. Happel, and M. A. Hnatow, Eds., vol. 715, pp. 247–269, Annals of the New York Academy of Sciences, 1994.
[26]
S. R. Dallimore and T. S. Collett, “Intrapermafrost gas hydrates from a deep core hole in the Mackenzie Delta, Northwest Territories, Canada,” Geology, vol. 23, no. 6, pp. 527–530, 1995.
[27]
R. A. Muller and G. J. MacDonald, Ice Ages and Astronomical Causes: Data, Spectral Analysis, and Mechanisms, Springer, Berlin, Germany, 2000.
[28]
L. A. Frakes, J. E. Francis, and J. I. Syktus, Climate Models of the Phanerozoic, Cambridge Univ. Press, Cambridge, UK, 1992.
K. Polsson, “Climate Change - Carbon dioxide,” http://www.islandnet.com/~kpolsson/climate/carbondioxide.htm.
[31]
K. L. Bice and J. Marotzke, “Could changing ocean circulation have destabilized methane hydrate at the Paleocene/Eocene boundary?” Paleoceanography, vol. 17, no. 2, Article ID 1018, 12 pages, 2002.
[32]
M. E. Katz, B. S. Cramer, G. S. Mountain, S. Katz, and K. G. Miller, “Uncorking the bottle: What triggered the Paleocene/Eocene thermal maximum metahane release?” Paleoceanography, vol. 16, no. 6, pp. 549–562, 2001.
[33]
J. A. Majorowicz and P. K. Hannigan, “Stability zone of natural gas hydrates in a permafrost-bearing region of the Beaufort-Mackenzie basin: study of a feasible energy source,” Natural Resources Research, vol. 9, no. 1, pp. 3–25, 2000.
[34]
A. S. Judge and J. A. Majorowicz, “Geothermal conditions for gas hydrate stability in the Beaufort-Mackenzie area—the global change aspect,” Paleogeography Paleoclimatology and Paleoecology, Global & Planetary Change Section, vol. 98, pp. 251–263, 1992.
[35]
J. A. Majorowicz and S. L. Smith, “Review of ground temperatures in the Mallik field area: a constraint to the methane hydrate stability,” in JAPEX/JNOC/GSC Mallik 2L-38 Gas Hydrate Research Well, Mackenzie Delta, Northwest Territories, Canada, S. R. Dallimore, T. Uchida, and T. S. Collett, Eds., vol. 544, pp. 45–56, Geological Survey of Canada Bulletin, 1999.
[36]
A. E. Taylor and A. S. Judge, Canadian geothermal data collection-Northern wells 1976-77, Geothermal Series Earth Physics Branch, EMR, 1977.
[37]
A. E. Taylor and A. S. Judge, Canadian geothermal data collection-Northern wells 1975, Geothermal Series Earth Physics Branch, EMR, 1976.
[38]
A. E. Taylor and A. S. Judge, Canadian geothermal data collection-Northern wells, Geothermal Series Earth Physics Branch, EMR, 1974.
[39]
A. E. Taylor, A. S. Judge, and V. S. Allen, “The automatic well temperature measuring system installed at Cape Allison C-47,offshore well, Arctic Islands of Canada: 2. Data retrieval and analysis of the thermal regime,” Journal of Canadian Petroleum Technology, vol. 28, pp. 95–101, 1989.
[40]
A. S. Judge, A. E. Taylor, and M. Burgess, Canadian geothermal data collection-Northern wells 1977-78, Geothermal Series Earth Physics Branch, EMR, 1979.
[41]
A. S. Judge, A. E. Taylor, M. Burgess, and V. S. Allen, Canadian geothermal data collection-Northern wells 1978-80, Geothermal Series Earth Physics Branch, EMR, 1981.
[42]
A. S. Judge, S. L. Smith, and J. A. Majorowicz, “The Current Distribution and Thermal Stability of Natural Gas Hydrates in the Canadian Polar Regions,” in Proceedings of the 4th, International Offshore and Polar Engineering Conference, pp. 307–314, Osaka, Japan, April 1994.
[43]
L. E. Lisiecki and M. E. Raymo, “A Pliocene-Pleistocene stack of 57 globally distributed benthic δ18O records,” Paleoceanography, vol. 20, no. 1, pp. 1–17, 2005.
[44]
T. Brent, CSPG Annual Meeting Poster, Canadian Soc. Petr. Geol. Annual Meeting, 2003.
[45]
J. A. Majorowicz and A. F. Embry, “Present heat flow and paleo-geothermal regime in the Canadian Arctic margin: analysis of industrial thermal data and coalification gradients,” Tectonophysics, vol. 291, no. 1–4, pp. 141–159, 1998.
[46]
D. Blackwell and M. Richards, Eds., Heat Flow Map of North America, SMU/AAPG, Tulsa, Okla, USA, 2004.
[47]
A. E. Taylor, A. Judge, and D. Desrochers, “Shoreline regression: its effect on permafrost and the geothermal regime, Canadian Arctic Archipelago,” in 4th International Conference on Permafrost, pp. 1239–1244, National Academy Press, 1983.
[48]
A. E. Taylor, “Modelling the thermal regime of permafrost and gas hydrate deposits to determine the impact of climate warming. Mallik field area,” in JAPEX/JNOC/GSC Mallik 2L-38 Gas Hydrate Research Well, Mackenzie Delta, Northwest Territories, Canada, SR Dallimore, T Uchida, and T. S. Collett, Eds., vol. 544, pp. 391–401, Geological Survey of Canada Bulletin, 1999.
[49]
R. I. Walcott, “Late Quaternary vertical movements in eastern North America: Quantitative evidence of glacio-isostatic rebound,” Reviews of Geophysics, vol. 10, pp. 849–884, 1972.
[50]
A. S. Dyke, “Holocene delevelling of Devon Island, Arctic Canada: implications for ice sheet geometry and crustal response,” Canadian Journal of Earth Sciences, vol. 35, no. 8, pp. 885–904, 1998.
[51]
A. S. Dyke, J. Hooper, and J. M. Savelle, “A history of sea ice in the Canadian Arctic archipelago based on postglacial remains of the bowhead whale (Balaena mysticetus),” Arctic, vol. 49, no. 3, pp. 235–255, 1996.
[52]
J. England, “Postglacial isobases and uplift curves from the Canadian and Greenland high Arctic,” Arct. Alp. Res., vol. 8, pp. 61–78, 1976.
[53]
W. R. Peltier, “Global glacial isostasy and the surface of the ice-age earth: The ICE-5G (VM2) model and GRACE,” Annual Review of Earth and Planetary Sciences, vol. 32, pp. 111–149, 2004.
[54]
W. R. Peltier, “Global glacial isostatic adjustment: Palaeogeodetic and space-geodetic tests of the ICE-4G (VM2) model,” Journal of Quaternary Science, vol. 17, no. 5-6, pp. 491–510, 2002.
[55]
J. England, “Glaciation and the evolution of the Canadian high arctic landscape,” Geology, vol. 15, no. 5, pp. 419–424, 1987.
[56]
J. England, N. Atkinson, J. Bednarski, A. S. Dyke, D. A. Hodgson, and C. ó Cofaigh, “The Innuitian Ice Sheet: configuration, dynamics and chronology,” Quaternary Science Reviews, vol. 25, no. 7-8, pp. 689–703, 2006.
[57]
S. J. Marshall and P. U. Clark, “Basal temperature evolution of North American ice sheets and implications for the 100-kyr cycle,” Geophysical Research Letters, vol. 29, no. 24, Article ID 2214, 4 pages, 2002.
[58]
F. Rolandone, J. C. Mareschal, and C. Jaupart, “Temperatures at the base of the Laurentide Ice Sheet inferred from borehole temperature data,” Geophysical Research Letters, vol. 30, no. 18, pp. 3–4, 2003.
[59]
A. J. Payne, “Limit cycles in the basal thermal regime of ice sheets,” Journal of Geophysical Research, vol. 100, no. 3, pp. 4249–4263, 1995.
[60]
A. E. Taylor and K. Wang, “Geothermal inversion of Canadian Arctic ground temperatures and effect of permafrost aggradation at emergent shorelines,” Geochemistry, Geophysics, Geosystems, vol. 9, no. 7, Article ID Q07019, 2008.
[61]
T. Sowers, “Late quaternary atmospheric CH4 isotope record suggests marine clathrates are stable,” Science, vol. 311, no. 5762, pp. 838–840, 2006.
[62]
E. G. Nisbet, “The end of the ice age,” Canadian Journal of Earth Sciences, vol. 27, pp. 148–157, 1990.
[63]
E. G. Nisbet, “Have sudden large releases of methane from geological reservoirs occurred since the Last Glacial Maximum, and could such releases occur again?” Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences, vol. 360, no. 1793, pp. 581–607, 2002.
