Beschreibung: Thermokarst lakes are thought to have been an important source of methane (CH4) during the last deglaciation when atmospheric CH4 concentrations increased rapidly. Here we demonstrate that meltwater from permafrost ice serves as an H source to CH4 production in thermokarst lakes, allowing for region-specific reconstructions of dD-CH4 emissions from Siberian and North American lakes. dD CH4 reflects regionally varying dD values of precipitation incorporated into ground ice at the time of its formation. Late Pleistocene-aged permafrost ground ice was the dominant H source to CH4 production in primary thermokarst lakes, whereas Holocene-aged permafrost ground ice contributed H to CH4 production in later generation lakes. We found that Alaskan thermokarst lake dD-CH4 was higher (-334 ± 17 per mil) than Siberian lake dD-CH4 (-381 ± 18 per mil). Weighted mean dD CH4 values for Beringian lakes ranged from -385 per mil to -382 per mil over the deglacial period. Bottom-up estimates suggest that Beringian thermokarst lakes contributed 15 ± 4 Tg CH4 /yr to the atmosphere during the Younger Dryas and 25 ± 5 Tg CH4 /yr during the Preboreal period. These estimates are supported by independent, top-down isotope mass balance calculations based on ice core dD-CH4 and d13C-CH4 records. Both approaches suggest that thermokarst lakes and boreal wetlands together were important sources of deglacial CH4.

Beschreibung: Some of the highest coastal erosion rates in the world are now occurring along non-bedrock, permafrost affected coastlines in the Arctic. Understanding how vulnerable Arctic coastlines are to current and future climate change is critical for resource management, subsistence hunting and gathering, and quantifying the flux of carbon and sediment from a terrestrial to marine environment. Observations since the 1970’s, show that pan-Arctic sea ice extent is decreasing by approximately 12 % per decade, with 2012 exhibiting the longest ice-free season on record. As a result, Arctic coastlines are vulnerable to wave-driven erosion for longer periods. Permafrost borehole temperatures show an overall warming trend, increasing susceptibility to thaw. While several studies already exist pointing at accelerating coastal erosion along the Beaufort Sea coast, studies for the Chukchi Sea coast of NW Alaska have remained inconclusive for the 1950-2003 period. Did recent dramatic changes in sea ice extent, with several sea ice minimum records since the mid 2000’s have an impact on the patterns and processes of coastal dynamics of the Chukchi Sea coast? Here we report on coastal change rates and key geomorphological processes occurring between 2003 and 2013 in comparison to coastal dynamics between 1950 and 2003 along the northern shoreline of the Seward Peninsula, Alaska, USA. Previous studies in our study area, focusing on 1950 to 2003, show rates of change ranging from -5.84 to 2.57 meters per year, indicating the occurrence of both erosion and aggradation. Our study shoreline is a complex system of barrier islands, sand spits, yedoma bluffs and drained thermokarst lake basins. The 1950-2003 coastal change data is based on aerial imagery covering 3 time steps (ca. 1950, ca. 1978, and 2003) that was analyzed by Lestak et al. 2010. To place recent coastal change dynamics since then in a spatial context, we conducted geomorphological analysis using 22 sub-meter resolution panchromatic World View 2 images from June 2013 and a five-meter resolution interferometric synthetic aperture radar derived digital elevation model acquired in summer 2012. We identified key geomorphological processes associated with coastal change and analyzed sediment redistribution between yedoma bluffs, lagoons and spits. Although relatively stable, ice wedge degradation was observed in yedoma bluff areas. Barrier islands, tidal channels, and overwash deposits showed significant variation in morphology during the study period. We further collected weather station data from Shishameref and Kotzebue, the two closest climate stations to the study area, and plan to extract sea ice and sea surface temperature data for the immediate region offshore our study coast. Our results illustrate the heterogeneous nature of coastal dynamics along the Arctic coastline and the need to acknowledge this when modelling future coastal response to sea ice decline and climate change.