Climate-sensitive northern lakes and ponds are critical components of methane release (original) (raw)

References

1. Kirschke, S. et al. Three decades of global methane sources and sinks. Nature Geosci. 6, 813–823 (2013).
   Google Scholar
2. Lehner, B. & Döll, P. Development and validation of a global database of lakes, reservoirs and wetlands. J. Hydrol. 296, 1–22 (2004).
   Google Scholar
3. Downing, J. A. et al. The global abundance and size distribution of lakes, ponds, and impoundments. Limnol. Oceanogr. 51, 2388–2397 (2006).
   Google Scholar
4. Smith, L. C., Sheng, Y. & MacDonald, G. M. A first pan-Arctic assessment of the influence of glaciation, permafrost, topography and peatlands on Northern Hemisphere lake distribution. Permafrost Periglac. 18, 201–208 (2007).
   Google Scholar
5. Bruhwiler, L. et al. CarbonTracker-CH4: an assimilation system for estimating emissions of atmospheric methane. Atmos. Chem. Phys. 14, 8269–8293 (2014).
   Google Scholar
6. Walter, K. M., Smith, L. C. & Stuart Chapin, F. Methane bubbling from northern lakes: present and future contributions to the global methane budget. Phil. Trans. R. Soc. A 365, 1657–1676 (2007).
   Google Scholar
7. Bastviken, D., Tranvik, L. J., Downing, J. A., Crill, P. M. & Enrich-Prast, A. Freshwater methane emissions offset the continental carbon sink. Science 331, 50–50 (2011).
   Google Scholar
8. Tan, Z. & Zhuang, Q. Arctic lakes are continuous methane sources to the atmosphere under warming conditions. Environ. Res. Lett. 10, 1–9 (2015).
   Google Scholar
9. Verpoorter, C., Kutser, T., Seekell, D. A. & Tranvik, L. J. A global inventory of lakes based on high-resolution satellite imagery. Geophys. Res. Lett. 41, 6396–6402 (2014).
   Google Scholar
10. Sepulveda-Jauregui, A., Walter Anthony, K. M., Martinez-Cruz, K., Greene, S. & Thalasso, F. Methane and carbon dioxide emissions from 40 lakes along a north–south latitudinal transect in Alaska. Biogeosciences 12, 3197–3223 (2015).
    Google Scholar
11. Greene, S., Walter Anthony, K. M., Archer, D., Sepulveda-Jauregui, A. & Martinez-Cruz, K. Modeling the impediment of methane ebullition bubbles by seasonal lake ice. Biogeosciences 11, 6791–6811 (2014).
    Google Scholar
12. Collins, M. et al. in Climate Change 2013: The Physical Science Basis (eds Stocker, T. F. et al.) 1029–1136 (IPCC, Cambridge Univ. Press, 2013).
    Google Scholar
13. Schuur, E. A. G. et al. Climate change and the permafrost carbon feedback. Nature 520, 171–179 (2015).
    Google Scholar
14. Schneider, P. & Hook, S. J. Space observations of inland water bodies show rapid surface warming since 1985. Geophys. Res. Lett. 37, L22405 (2010).
    Google Scholar
15. Dibike, Y., Prowse, T., Saloranta, T. & Ahmed, R. Response of Northern Hemisphere lake-ice cover and lake-water thermal structure patterns to a changing climate. Hydrol. Process. 25, 2942–2953 (2011).
    Google Scholar
16. Wik, M. et al. Energy input is primary controller of methane bubbling in subarctic lakes. Geophys. Res. Lett. 41, 555–560 (2014).
    Google Scholar
17. Thornton, B. F., Wik, M. & Crill, P. M. Climate-forced changes in available energy and methane bubbling from subarctic lakes. Geophys. Res. Lett. 42, 1936–1942 (2015).
    Google Scholar
18. Prowse, T. D. & Stephenson, R. L. The relationship between winter lake cover, radiation receipts and the oxygen deficit in temperate lakes. Atmos. Ocean 24, 386–403 (1986).
    Google Scholar
19. Rouse, W. R. et al. Effects of climate change on the freshwaters of Arctic and subarctic North America. Hydrol. Process. 11, 873–902 (1997).
    Google Scholar
20. Natchimuthu, S., Panneer Selvam, B. & Bastviken, D. Influence of weather variables on methane and carbon dioxide flux from a shallow pond. Biogeochemistry 119, 403–413 (2014).
    Google Scholar
21. Zeikus, J. G. & Winfrey, M. R. Temperature limitation of methanogenesis in aquatic sediments. Appl. Environ. Microbiol. 31, 99–107 (1976).
    Google Scholar
22. Kelly, C. A. & Chynoweth, D. P. The contributions of temperature and of the input of organic matter in controlling rates of sediment methanogenesis. Limnol. Oceanogr. 26, 891–897 (1981).
    Google Scholar
23. Yvon-Durocher, G. et al. Methane fluxes show consistent temperature dependence across microbial to ecosystem scales. Nature 507, 488–491 (2014).
    Google Scholar
24. Martens, C. S. & Val Klump, J. Biogeochemical cycling in an organic-rich coastal marine basin—I. Methane sediment–water exchange processes. Geochim. Cosmochim. Acta 44, 471–490 (1980).
    Google Scholar
25. Bastviken, D., Cole, J., Pace, M. & Tranvik, L. Methane emissions from lakes: dependence of lake characteristics, two regional assessments, and a global estimate. Glob. Biogeochem. Cycles 18, GB4009 (2004).
    Google Scholar
26. Walter Anthony, K. M. & Anthony, P. Constraining spatial variability of methane ebullition seeps in thermokarst lakes using point process models. J. Geophys. Res. Biogeosci. 118, 1–20 (2013).
    Google Scholar
27. Rasilo, T., Prairie, Y. T. & del Giorgio, P. A. Large-scale patterns in summer diffusive CH4 fluxes across boreal lakes, and contribution to diffusive C emissions. Glob. Change Biol. 21, 1124–1139 (2014).
    Google Scholar
28. Wik, M., Crill, P. M., Varner, R. K. & Bastviken, D. Multiyear measurements of ebullitive methane flux from three subarctic lakes. J. Geophys. Res. Biogeosci. 118, 1307–1321 (2013).
    Google Scholar
29. Tranvik, L. J. et al. Lakes and reservoirs as regulators of carbon cycling and climate. Limnol. Oceangr. 54, 2298–2314 (2009).
    Google Scholar
30. Schuur, E. A. G. et al. Expert assessment of vulnerability of permafrost carbon to climate change. Climatic Change 119, 359–374 (2013).
    Google Scholar
31. Avis, C. A., Weaver, A. J. & Meissner, K. J. Reduction in areal extent of high-latitude wetlands in response to permafrost thaw. Nature Geosci. 4, 444–448 (2011).
    Google Scholar
32. van Huissteden, J. et al. Methane emissions from permafrost thaw lakes limited by lake drainage. Nature Clim. Change 1, 119–123 (2011).
    Google Scholar
33. Bouchard, F., Francus, P., Pienitz, R., Laurion, I. & Feyte, S. Subarctic thermokarst ponds: investigating recent landscape evolution and sediment dynamics in thawed permafrost of northern Québec (Canada). Arct. Antarct. Alp. Res. 46, 251–271 (2014).
    Google Scholar
34. Peterson, B. J. Trajectory shifts in the Arctic and subarctic freshwater cycle. Science 313, 1061–1066 (2006).
    Google Scholar
35. McClelland, J. W., Déry, S. J., Peterson, B. J., Holmes, R. M. & Wood, E. F. A pan-Arctic evaluation of changes in river discharge during the latter half of the 20th century. Geophys. Res. Lett. 33, L06715 (2006).
    Google Scholar
36. Boereboom, T., Depoorter, M., Coppens, S. & Tison, J. L. Gas properties of winter lake ice in northern Sweden: implication for carbon gas release. Biogeosciences 9, 827–838 (2012).
    Google Scholar
37. Petrescu, A. M. R. et al. Modeling regional to global CH4 emissions of boreal and Arctic wetlands. Glob. Biogeochem. Cycles 24, 1–12 (2010).
    Google Scholar
38. Melton, J. R. et al. Present state of global wetland extent and wetland methane modelling: conclusions from a model inter-comparison project (WETCHIMP). Biogeosciences 10, 753–788 (2013).
    Google Scholar
39. Houweling, S., Kaminski, T., Dentener, F. J., Lelieveld, J. & Heimann, M. Inverse modeling of methane sources and sinks using the adjoint of a global transport model. J. Geophys. Res. 104, 26137–26160 (1999).
    Google Scholar
40. Krol, M. Can the variability in tropospheric OH be deduced from measurements of 1,1,1-trichloroethane (methyl chloroform)? J. Geophys. Res. 108, 4125 (2003).
    Google Scholar
41. Bousquet, P., Hauglustaine, D. A., Peylin, P., Carouge, C. & Ciais, P. Two decades of OH variability as inferred by an inversion of atmospheric transport and chemistry of methyl chloroform. Atmos. Chem. Phys. 5, 2635–2656 (2005).
    Google Scholar
42. Montzka, S. A. et al. Small interannual variability of global atmospheric hydroxyl. Science 331, 67–69 (2011).
    Google Scholar
43. Downing, J. Emerging global role of small lakes and ponds: little things mean a lot. Limnetica 29, 9–24 (2010).
    Google Scholar
44. Whitfield, C. J., Baulch, H. M., Chun, K. P. & Westbrook, C. J. Beaver-mediated methane emission: the effects of population growth in Eurasia and the Americas. AMBIO 44, 7–15 (2015).
    Google Scholar
45. Hartmann, D. L. et al. in Climate Change 2013: The Physical Science Basis (eds Stocker, T. F. et al.) 159–254 (IPCC, Cambridge Univ. Press, 2013).
    Google Scholar
46. MacIntyre, S. et al. Climate-related variations in mixing dynamics in an Alaskan Arctic lake. Limnol. Oceanogr. 54, 2401–2417 (2009).
    Google Scholar
47. Schnurrenberger, D., Russell, J. & Kelts, K. Classification of lacustrine sediments based on sedimentary components. J. Paleolimnol. 29, 141–154 (2003).
    Google Scholar
48. McGinnis, D. F., Greinert, J., Artemov, Y., Beaubien, S. E. & Wüest, A. Fate of rising methane bubbles in stratified waters: how much methane reaches the atmosphere? J. Geophys. Res. 111, C09007 (2006).
    Google Scholar
49. Phelps, A. R., Peterson, K. M. & Jeffries, M. O. Methane efflux from high-latitude lakes during spring ice melt. J. Geophys. Res. 103, 29029–29036 (1998).
    Google Scholar
50. Laurion, I. et al. Variability in greenhouse gas emissions from permafrost thaw ponds. Limnol. Oceanogr. 55, 115–133 (2010).
    Google Scholar
51. Sellmann, P. V., Brown, J., Lewellen, R. I., McKim, H. & Merry, C. The Classification and Geomorphic Implications of Thaw Lakes on the Arctic Coastal Plain, Alaska Research Report 344 (Cold Regions Research and Engineering Laboratory, 1975).
    Google Scholar
52. Grosse, G., Jones, B. & Arp, C. Thermokarst lakes, drainage, and drained basins. Treat. Geomorph. 8, 325–353 (2013).
    Google Scholar
53. Grosse, G. et al. Distribution of Late Pleistocene Ice-Rich Syngenetic Permafrost of the Yedoma Suite in East and Central Siberia, Russia Open File Report 2013–1078 (USGS, 2013).
    Google Scholar
54. Strauss, J. et al. The deep permafrost carbon pool of the yedoma region in Siberia and Alaska. Geophys. Res. Lett. 40, 6165–6170 (2013).
    Google Scholar
55. Walter Anthony, K. et al. A shift of thermokarst lakes from carbon sources to sinks during the Holocene epoch. Nature 511, 452–456 (2014).
    Google Scholar
56. Walter, K. M., Zimov, S. A., Chanton, J. P., Verbyla, D. & Chapin, F. S. Methane bubbling from Siberian thaw lakes as a positive feedback to climate warming. Nature 443, 71–75 (2006).
    Google Scholar
57. Anthony, K. M. W., Anthony, P., Grosse, G. & Chanton, J. Geologic methane seeps along boundaries of Arctic permafrost thaw and melting glaciers. Nature Geosci. 5, 1–8 (2012).
    Google Scholar
58. Brosius, L. S. et al. Using the deuterium isotope composition of permafrost meltwater to constrain thermokarst lake contributions to atmospheric CH4 during the last deglaciation. J. Geophys. Res. 117, G01022 (2012).
    Google Scholar
59. Kessler, M. A., Plug, L. J. & Walter Anthony, K. M. Simulating the decadal- to millennial-scale dynamics of morphology and sequestered carbon mobilization of two thermokarst lakes in NW Alaska. J. Geophys. Res. 117, 1–22 (2012).
    Google Scholar
60. Bowen, R. G., Dallimore, S. R., Côte, M. M., Wright, J. F. & Lorenson, T. D. in Proceedings of Ninth International Conference on Permafrost (eds Kane, D. L. & Hinkel, K. M.) 171–176 (Institute of Northern Engineering, Univ. Alaska Fairbanks, 2008).
    Google Scholar
61. Manasypov, R. M., Pokrovsky, O. S., Kirpotin, S. N. & Shirokova, L. S. Thermokarst lake waters across the permafrost zones of western Siberia. Cryosphere 8, 1177–1193 (2014).
    Google Scholar
62. Tank, S. E., Lesack, L. F. W., Gareis, J. A. L., Osburn, C. L. & Hesslein, R. H. Multiple tracers demonstrate distinct sources of dissolved organic matter to lakes of the Mackenzie Delta, western Canadian Arctic. Limnol. Oceanogr. 56, 1297–1309 (2011).
    Google Scholar
63. Hinkel, K. M., Frohn, R. C., Nelson, F. E., Eisner, W. R. & Beck, R. A. Morphometric and spatial analysis of thaw lakes and drained thaw lake basins in the western Arctic Coastal Plain, Alaska. Permafrost Periglac. 16, 327–341 (2005).
    Google Scholar
64. Prowse, T. et al. Past and future changes in Arctic lake and river ice. AMBIO 40, 53–62 (2011).
    Google Scholar
65. Sharma, S. & Magnuson, J. J. Oscillatory dynamics do not mask linear trends in the timing of ice breakup for Northern Hemisphere lakes from 1855 to 2004. Climatic Change 124, 835–847 (2014).
    Google Scholar
66. Surdu, C. M., Duguay, C. R., Brown, L. C. & Fernández Prieto, D. Response of ice cover on shallow lakes of the North Slope of Alaska to contemporary climate conditions (1950–2011): radar remote-sensing and numerical modeling data analysis. Cryosphere 8, 167–180 (2014).
    Google Scholar
67. Smith, L. C., Sheng, Y., MacDonald, G. M. & Hinzman, L. D. Disappearing Arctic lakes. Science 308, 1429–1429 (2005).
    Google Scholar
68. Andresen, C. G. & Lougheed, V. L. Disappearing Arctic tundra ponds: fine-scale analysis of surface hydrology in drained thaw lake basins over a 65 year period (1948–2013). J. Geophys. Res. Biogeosci. 120, 466–479 (2015).
    Google Scholar
69. Kicklighter, D. W. et al. Insights and issues with simulating terrestrial DOC loading of Arctic river networks. Ecol. Appl. 23, 1817–1836 (2013).
    Google Scholar
70. Wetzel, G. R. Limnology: Lake and River Ecosystems (Academic, 2001).
    Google Scholar
71. Belyea, L. R. & Clymo, R. S. in Patterned Mires and Mire Pools: Origin and Development, Flora and Fauna (eds Standen, V., Tallis, J. & Meade, R.) 55–65 (British Ecological Society, 1999).
    Google Scholar
72. Gao, X. et al. Permafrost degradation and methane: low risk of biogeochemical climate-warming feedback. Environ. Res. Lett. 8, 035014 (2013).
    Google Scholar
73. Brown, J., Ferrians, O. J. J., Heginbottom, J. A. & Melnikov, E. S. Circum-Arctic Map of Permafrost and Ground-Ice Conditions (National Snow and Ice Data Center, 1998, revised February 2001); http://go.nature.com/JQIke5
    Google Scholar
74. Olson, D. M. et al. Terrestrial ecoregions of the world: a new map of life on Earth. BioScience 51, 933–938 (2001).
    Google Scholar
75. Peel, M. C., Finlayson, B. L. & McMahon, T. A. Updated world map of the Köppen-Geiger climate classification. Hydrol. Earth. Syst. Sci. 11, 1633–1644 (2007).
    Google Scholar
76. Chen, D. & Chen, H. W. Using the Köppen classification to quantify climate variation and change: an example for 1901–2010. Environ. Devel. 6, 69–79 (2013).
    Google Scholar

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