Spatial variation in shallow sediment methane sources and cycling on the Alaskan Beaufort Sea Shelf/Slope

The MITAS (Methane in the Arctic Shelf/Slope) expedition was conducted during September, 2009 onboard the U.S. Coast Guard Cutter (USCGC) Polar Sea (WAGB-11), on the Alaskan Shelf/Slope of the Beaufort Sea. Expedition goals were to investigate spatial variations in methane source(s), vertical methane flux in shallow sediments (<10 mbsf), and methane contributions to shallow sediment carbon cycling. Three nearshore to offshore transects were conducted across the slope at locations approximately 200 km apart in water column depths from 20 to 2100 m. Shallow sediments were collected by piston cores and vibracores and samples were analyzed for sediment headspace methane (CH4), porewater sulfate (SO42−), chloride (Cl−), and dissolved inorganic carbon (DIC) concentrations, and CH4 and DIC stable carbon isotope ratios (δ13C). Downward SO42− diffusion rates estimated from sediment porewater SO42− profiles were between −15.4 and −154.8 mmol m−2 a−1 and imply a large spatial variation in vertical CH4 flux between transects in the study region. Lowest inferred CH4 fluxes were estimated along the easternmost transect. Higher inferred CH4 flux rates were observed in the western transects. Sediment headspace δ13CCH4δ13CCH4 values ranged from −138 to −48‰, suggesting strong differences in shallow sediment CH4 cycling within and among sample locations. Measured porewater DIC concentrations ranged from 2.53 mM to 79.39 mM with δ13CDIC values ranging from −36.4‰ to 5.1‰. Higher down-core DIC concentrations were observed to occur with lower δ13C where an increase in δ13CCH4δ13CCH4 was measured, indicating locations with active anaerobic oxidation of methane. Shallow core CH4 production was inferred at the two western most transects (i.e. Thetis Island and Halkett) through observations of low δ13CCH4δ13CCH4 coupled with elevated DIC concentrations. At the easternmost Hammerhead transect and offshore locations, δ13CCH4δ13CCH4 and DIC concentrations were not coupled suggesting less rapid methane cycling. Results from the MITAS expedition represent one of the most comprehensive studies of methane source(s) and vertical methane flux in shallow sediments of the U.S. Alaskan Beaufort Shelf to date and show geospatially variable sediment methane flux that is highly influenced by the local geophysical environment.

[1]  David L. Valentine,et al.  Biogeochemistry and microbial ecology of methane oxidation in anoxic environments: a review , 2002, Antonie van Leeuwenhoek.

[2]  D. Burdige,et al.  Anaerobic oxidation of methane and the stoichiometry of remineralization processes in continental margin sediments , 2011 .

[3]  R. Macdonald,et al.  Oceanography of the Canadian Shelf of the Beaufort Sea: A Setting for Marine Life , 2002 .

[4]  M. T. Jorgenson,et al.  Classification of the Alaskan Beaufort Sea Coast and estimation of carbon and sediment inputs from coastal erosion , 2005 .

[5]  G. Dickens Sulfate profiles and barium fronts in sediment on the Blake Ridge: present and past methane fluxes through a large gas hydrate reservoir , 2001 .

[6]  D. Valentine,et al.  New perspectives on anaerobic methane oxidation. , 2000, Environmental microbiology.

[7]  E. Gorham Northern Peatlands: Role in the Carbon Cycle and Probable Responses to Climatic Warming. , 1991, Ecological applications : a publication of the Ecological Society of America.

[8]  Robert A. Berner,et al.  Methane Production in the Interstitial Waters of Sulfate-Depleted Marine Sediments , 1974, Science.

[9]  A. S. Naidu,et al.  Sources and dispersal patterns of clay minerals in surface sediments from the continental-shelf areas off Alaska , 1983 .

[10]  W. Oechel,et al.  The effects of climate charge on land-atmosphere feedbacks in arctic tundra regions. , 1994, Trends in ecology & evolution.

[11]  K. Kvenvolden,et al.  Potential effects of gas hydrate on human welfare. , 1999, Proceedings of the National Academy of Sciences of the United States of America.

[12]  J. Chanton,et al.  Radiocarbon in marine bacteria: Evidence for the ages of assimilated carbon , 1999 .

[13]  L. Wehrmann,et al.  Coupled organic and inorganic carbon cycling in the deep subseafloor sediment of the northeastern Bering Sea Slope (IODP Exp. 323) , 2011 .

[14]  N. Blair,et al.  Carbon remineralization in the Amazon–Guianas tropical mobile mudbelt: A sedimentary incinerator , 2006 .

[15]  Robert A. Berner,et al.  An idealized model of dissolved sulfate distribution in recent sediments , 1964 .

[16]  M. Latif,et al.  Rising Arctic Ocean temperatures cause gas hydrate destabilization and ocean acidification , 2011 .

[17]  T. Sowers Late Quaternary Atmospheric CH4 Isotope Record Suggests Marine Clathrates Are Stable , 2006, Science.

[18]  Bo Barker Jørgensen,et al.  Diffusion coefficients of sulfate and methane in marine sediments: Influence of porosity , 1993 .

[19]  S. Joye,et al.  The sulfur biogeochemistry of chemosynthetic cold seep communities, gulf of Mexico, USA , 2004 .

[20]  R. Berner Sulfate reduction and the rate of deposition of marine sediments , 1978 .

[21]  Alexei V. Milkov,et al.  Preliminary assessment of resources and economic potential of individual gas hydrate accumulations in the Gulf of Mexico continental slope , 2003 .

[22]  Quan Hua,et al.  14CH4 Measurements in Greenland Ice: Investigating Last Glacial Termination CH4 Sources , 2009, Science.

[23]  R. Sassen,et al.  Archaeal lipid biomarkers and isotopic evidence of anaerobic methane oxidation associated with gas hydrates in the Gulf of Mexico , 2003 .

[24]  K. Knittel,et al.  Anaerobic oxidation of methane: progress with an unknown process. , 2009, Annual review of microbiology.

[25]  W. Borowski,et al.  Marine pore-water sulfate profiles indicate in situ methane flux from underlying gas hydrate , 1996 .

[26]  C. Ruppel,et al.  Minimum distribution of subsea ice‐bearing permafrost on the U.S. Beaufort Sea continental shelf , 2012 .

[27]  R. Coffin,et al.  Methane hydrate exploration on the mid Chilean coast: A geochemical and geophysical survey , 2007 .

[28]  Antje Boetius,et al.  The anaerobic oxidation of methane and sulfate reduction in sediments from Gulf of Mexico cold seeps , 2004 .

[29]  A. Savvichev,et al.  Reservoir of dissolved methane in the water column of the seas of the Russian Arctic region , 2011 .

[30]  C. Paull,et al.  Geochemical constraints on the distribution of gas hydrates in the Gulf of Mexico , 2005 .

[31]  R. Plummer,et al.  Compound-Specific Stable Carbon Isotope Analysis of Low-Concentration Complex Hydrocarbon Mixtures from Natural Gas Hydrate Systems , 2005 .

[32]  Michael J. Whiticar,et al.  Carbon and hydrogen isotope systematics of bacterial formation and oxidation of methane , 1999 .

[33]  R. M. Owen,et al.  Dissociation of oceanic methane hydrate as a cause of the carbon isotope excursion at the end of the Paleocene , 1995 .

[34]  K. Kvenvolden Methane hydrate in the global organic carbon cycle , 2002 .

[35]  A. Boetius,et al.  Control of sulfate pore-water profiles by sedimentary events and the significance of anaerobic oxidation of methane for the burial of sulfur in marine sediments , 2003 .

[36]  R. Boswell,et al.  Current perspectives on gas hydrate resources , 2011 .

[37]  Warren T. Wood,et al.  Analysis of methane and sulfate flux in methane-charged sediments from the Mississippi Canyon, Gulf of Mexico , 2008 .

[38]  J. Greinert,et al.  Diversity and biogeochemical structuring of bacterial communities across the Porangahau ridge accretionary prism, New Zealand. , 2011, FEMS microbiology ecology.

[39]  G. Panteleev,et al.  The distribution of methane on the Siberian Arctic shelves: Implications for the marine methane cycle , 2005 .

[40]  L. Smith,et al.  Amplified carbon release from vast West Siberian peatlands by 2100 , 2004 .

[41]  I. Leifer,et al.  Geochemical and geophysical evidence of methane release over the East Siberian Arctic Shelf , 2010 .

[42]  T. Collett GEOLOGIC AND ENGINEERING CONTROLS ON THE PRODUCTION OF PERMAFROST-ASSOCIATED GAS HYDRATE ACCUMULATIONS , 2008 .

[43]  Gerald R. Dickens,et al.  Heat and salt inhibition of gas hydrate formation in the northern Gulf of Mexico , 2005 .

[44]  S. Boehme,et al.  A MASS BALANCE OF 13C AND 12C IN AN ORGANIC-RICH METHANE-PRODUCING MARINE SEDIMENT , 1996 .

[45]  Olaf Pfannkuche,et al.  A marine microbial consortium apparently mediating anaerobic oxidation of methane , 2000, Nature.

[46]  S. Dallimore,et al.  GAS HYDRATES ASSOCIATED WITH DEEP PERMAFROST IN THE MACKENZIE DELTA, N.W.T., CANADA: REGIONAL OVERVIEW , 1998 .

[47]  Mark H. Edwards,et al.  Seafloor evidence for ice shelf flow across the Alaska–Beaufort margin of the Arctic Ocean , 2008 .

[48]  R. Howarth,et al.  Salt Marsh Detritus: An Alternative Interpretation of Stable Carbon Isotope Ratios and the Fate of Spartina alterniflora , 1980 .

[49]  R. Pancost,et al.  Biomarker Evidence for Widespread Anaerobic Methane Oxidation in Mediterranean Sediments by a Consortium of Methanogenic Archaea and Bacteria , 2000, Applied and Environmental Microbiology.

[50]  M. Torres,et al.  Formation of modern and Paleozoic stratiform barite at cold methane seeps on continental margins , 2003 .

[51]  Gerald R. Dickens,et al.  Rhizon Sampling of Pore Waters on Scientific Drilling Expeditions: An Example from the IODP Expedition 302, Arctic Coring Expedition (ACEX) , 2007 .

[52]  W. Borowski,et al.  Global and local variations of interstitial sulfate gradients in deep-water, continental margin sediments: Sensitivity to underlying methane and gas hydrates , 1999 .

[53]  Timothy S. Collett,et al.  Intrapermafrost gas hydrates from a deep core hole in the Mackenzie Delta, Northwest Territories, Canada , 1995 .

[54]  G. Dickens,et al.  Pore water profiles and authigenic mineralization in shallow marine sediments above the methane-charged system on Umitaka Spur, Japan Sea , 2007 .

[55]  K. Osadetz,et al.  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 , 2010 .

[56]  Peter G. Brewer,et al.  Methane-consuming archaebacteria in marine sediments , 1999, Nature.

[57]  P. Aharon,et al.  Microbial sulfate reduction rates and sulfur and oxygen isotope fractionations at oil and gas seeps in deepwater Gulf of Mexico , 2000 .

[58]  Hailong Lu,et al.  Experimental studies on the possible influences of composition changes of pore water on the stability conditions of methane hydrate in marine sediments , 2005 .

[59]  L. Cifuentes,et al.  Stable isotope evidence for alternative bacterial carbon sources in the Gulf of Mexico , 1998 .

[60]  G. Myhre,et al.  Strong atmospheric chemistry feedback to climate warming from Arctic methane emissions , 2011 .

[61]  M. E. Mackay,et al.  Amplitude versus offset modeling of the bottom simulating reflection associated with submarine gas hydrates , 1997 .

[62]  Kenneth H. Dunton,et al.  The nearshore western Beaufort Sea ecosystem: Circulation and importance of terrestrial carbon in arctic coastal food webs , 2006 .

[63]  T. Treude,et al.  Anaerobic oxidation of methane and sulfate reduction along the Chilean continental margin , 2005 .

[64]  N. Blair,et al.  The persistence of memory: The fate of ancient sedimentary organic carbon in a modern sedimentary system , 2003 .

[65]  E. Delong,et al.  Methane-Consuming Archaea Revealed by Directly Coupled Isotopic and Phylogenetic Analysis , 2001, Science.

[66]  R. Macdonald,et al.  The role of depositional regime on carbon transport and preservation in Arctic Ocean sediments , 2004 .