Abstract
Abstract. Frozen debris lobes (FDLs) are elongated, lobate permafrost features that mostly move through shear in zones near their bases. We present a comprehensive overview of eight FDLs within the Dalton Highway corridor (southern Brooks Range, Alaska), including their catchment geology and rock strengths, lobe soil characteristics, surface movement measurements collected between 2012 and 2015, and analysis of historic and modern imagery from 1955 to 2014. Field mapping and rock strength data indicate that the metasedimentary and metavolcanic bedrock forming the majority of the lobe catchments has very low to medium strength and is heavily fractured, thus easily contributing to FDL formation. The eight investigated FDLs consist of platy rocks typical of their catchments, organic debris, and an ice-poor soil matrix; massive ice, however, is present within FDLs as infiltration ice, concentrated within cracks open to the surface. Exposure of infiltration ice in retrogressive thaw slumps (RTSs) and associated debris flows leads to increased movement and various stages of destabilization, resulting in morphological differences among the lobes. Analysis of historic imagery indicates that movement of the eight investigated FDLs has been asynchronous over the study period, and since 1955, there has been an overall increase in movement rates of the investigated FDLs. The formation of surface features, such as cracks, scarps, and RTSs, suggests that the increased movement rates correlate to general instability, and even at their current distances, FDLs are impacting infrastructure through increased sediment mobilization. FDL-A is the largest of the investigated FDLs. As of August 2015, FDL-A was 39.2 m from the toe of the Dalton Highway embankment. Based on its current distance and rate of movement, we predict that FDL-A will reach the Dalton Highway alignment by 2023.
Highlights
An atmospheric temperature rise has been identified as unequivocal by the Intergovernmental Panel on Climate Change (IPCC), with greater and faster temperature increase and an overall precipitation increase demonstrated at northern latitudes (Stocker et al, 2013)
(1) How does the bedrock source geology contribute to Frozen debris lobes (FDLs) morphology? (2) Are the investigated FDLs consistent in composition and morphology? (3) Has the movement of these FDLs been synchronous? (4) Have their rates of movement changed over time? (5) How can we describe the origin of these features? (6) How are FDLs impacting infrastructure? In an effort to answer these questions, in this paper we present for the first time a comprehensive overview of eight different FDLs within the Dalton Highway corridor
Subsurface measurements within FDL-A indicate that this frozen debris lobe moves predominantly through shear in a zone 20.6 to 22.8 m below ground surface, with temperature-dependent internal flow as a secondary movement mechanism (Darrow et al, 2015; Simpson et al, 2016)
Summary
An atmospheric temperature rise has been identified as unequivocal by the Intergovernmental Panel on Climate Change (IPCC), with greater and faster temperature increase and an overall precipitation increase demonstrated at northern latitudes (Stocker et al, 2013). Analysis of field data collected throughout Arctic and subarctic areas corroborates with IPCC’s findings, demonstrating an overall permafrost temperature rise (Christiansen et al, 2010; Romanovsky et al, 2010; Smith et al, 2010). Slopes in permafrost areas are in danger of instability with rising temperatures. An increase in infrastructure construction may occur in northern regions, including Alaska, as Arctic countries focus on economic development (EOP, 2014; Sevunts, 2013). Recognizing areas of slope instability and quantifying historic and potential movement become progressively important as climate changes and northern regions see increasing development
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