Soil Moisture Redistribution and Its Effect on Inter-Annual Active Layer Temperature and Thickness Variations in a Dry Loess Terrace in Adventdalen, Svalbard

Soil Moisture Redistribution and Its Effect on Inter-Annual Active Layer Temperature and Thickness Variations in a Dry Loess Terrace in Adventdalen, Svalbard

The Cryosphere, 11, 635–651, 2017 www.the-cryosphere.net/11/635/2017/ doi:10.5194/tc-11-635-2017 © Author(s) 2017. CC Attribution 3.0 License. Soil moisture redistribution and its effect on inter-annual active layer temperature and thickness variations in a dry loess terrace in Adventdalen, Svalbard Carina Schuh1, Andrew Frampton1,2, and Hanne Hvidtfeldt Christiansen3 1Department of Physical Geography, Stockholm University, Stockholm, Sweden 2Bolin Centre for Climate Change, Stockholm University, Stockholm, Sweden 3Department of Arctic Geology, The University Centre in Svalbard, Longyearbyen, Norway Correspondence to: Andrew Frampton ([email protected]) Received: 11 July 2016 – Discussion started: 10 August 2016 Revised: 5 January 2017 – Accepted: 18 January 2017 – Published: 28 February 2017 Abstract. High-resolution field data for the period 2000– ing active layer thickness (0.8 cm yr−1, observed and 0.3 to 2014 consisting of active layer and permafrost temperature, 0.8 cm yr−1, modelled) during the 14-year study period. active layer soil moisture, and thaw depth progression from the UNISCALM research site in Adventdalen, Svalbard, is combined with a physically based coupled cryotic and hy- drogeological model to investigate active layer dynamics. 1 Introduction The site is a loess-covered river terrace characterized by dry conditions with little to no summer infiltration and an un- Permafrost environments have been identified as key com- saturated active layer. A range of soil moisture character- ponents of the global climate system given their influence istic curves consistent with loess sediments is considered on energy exchanges, hydrological processes, carbon bud- and their effects on ice and moisture redistribution, heat gets and natural hazards (Riseborough et al., 2008; Schuur et flux, energy storage through latent heat transfer, and ac- al., 2015). Over the last 30 years, air temperatures in polar re- tive layer thickness is investigated and quantified based on gions have increased by 0.6 ◦C per decade, which is twice the hydro-climatic site conditions. Results show that soil mois- global average (IPCC, 2013). On Svalbard, long-term records ture retention characteristics exhibit notable control on ice indicate an increase in mean annual air temperature of 0.2 ◦C distribution and circulation within the active layer through per decade since the beginning of the 20th century (Humlum cryosuction and are subject to seasonal variability and site- et al., 2011), and permafrost warming has been detected to a specific surface temperature variations. The retention char- depth of 60 m based on borehole measurements (Isaksen et acteristics also impact unfrozen water and ice content in the al., 2007). The relationship between climate and permafrost permafrost. Although these effects lead to differences in thaw temperatures is, however, highly complex. Changes in active progression rates, the resulting inter-annual variability in ac- layer thickness can be buffered from effects of changing air tive layer thickness is not large. Field data analysis reveals temperatures by vegetation, snow cover, and permafrost ice that variations in summer degree days do not notably affect content and its thermal state, as well as by variable heat and the active layer thaw depths; instead, a cumulative winter de- water flows occurring in the active layer. The active layer is gree day index is found to more significantly control inter- important in cold regions, where thermal and hydrological annual active layer thickness variation at this site. A tendency processes determine local phenomena such as erosion, and of increasing winter temperatures is found to cause a gen- hydrological and ecosystem changes (Karlsson et al., 2012; eral warming of the subsurface down to 10 m depth (0.05 to Lyon et al., 2009; Walvoord and Kurylyk, 2016; Walvoord 0.26 ◦C yr−1, observed and modelled) including an increas- and Striegl, 2007), and has implications for solute and carbon transport (Frampton and Destouni, 2015; Giesler et al., 2014; Published by Copernicus Publications on behalf of the European Geosciences Union. 636 C. Schuh et al.: Soil moisture redistribution and its effect on inter-annual active layer temperature Jantze et al., 2013) and the global carbon–climate feedback 2014; McKenzie et al., 2007; Painter, 2011). This has enabled (Tarnocai et al., 2009). studies on effects of permafrost degradation on changes in Both soil moisture and the thickness of the active layer groundwater flows (Kurylyk et al., 2016; Scheidegger and have been identified as essential climate variables (GCOS, Bense, 2014; Sjöberg et al., 2016), in particular showing ex- 2015). Soil moisture is an important variable for energy ex- pected increase in base flow and decrease in seasonal vari- change and governs the processes occurring at the land– ability in discharge under warming (Frampton et al., 2013, atmosphere interface by partitioning incoming solar radia- 2011; Walvoord et al., 2012) and increased pathway lengths tion into fluxes of latent and sensible heat. Also, soil mois- and delays in solute mass transport and breakthrough due ture controls subsurface physical properties such as thermal to non-linear active layer thickness increase (Frampton and conductivity and heat capacity, so that the movement and dis- Destouni, 2015). tribution of moisture within the subsurface is essential for un- In this study, a comprehensive long-term monitoring data derstanding the water and heat balance of the ground, partic- set collected between 2000 and 2014 at the UNISCALM re- ularly in cold climates (Wu et al., 2015). Still, most studies on search site in Adventdalen, Svalbard, which includes ground permafrost thaw projections mainly investigate the structural temperature, soil moisture, and active layer thaw depth pro- uncertainty in climate models, whereas the parametric uncer- gression, is applied to a physically based numerical model for tainty in soil properties is barely accounted for (Harp et al., partially frozen ground to investigate subsurface processes 2016). Active layer thickness, in contrast, is one of the most controlling active layer dynamics. This site is characterized distinct indicators of permafrost change, which is why the re- by little precipitation and dry unsaturated conditions in the sponse of the active layer to climatic variations has been stud- active layer. In this particular environment, soil water reten- ied using climatic and ground thermal monitoring in several tion is a critical but also highly uncertain parameter, which Arctic regions (Frauenfeld, 2004; Lafrenière et al., 2013; Os- we investigate based on a range of characteristic retention terkamp, 2007). On Svalbard, Roth and Boike (2001) quanti- curves commonly ascribed to the dominant sediment type fied the soil thermal properties and conductive heat fluxes for (silt loam) of the location. The aim is to study how soil an experimental site near Ny-Ålesund based on subsurface moisture retention properties affect moisture and ice redis- temperature data and soil moisture measurements. Akerman tribution as well as subsurface temperature and active layer (2005) monitored active layer depths over several decades thickness variations in the partially saturated active layer un- in the Kapp Linné area with regard to periglacial slope pro- der multiple freeze–thaw cycles. Using a scenario analysis cesses, and found active layer deepening to correlate well approach, different soil moisture retention properties are ex- with increased air temperature. Isaksen et al. (2007) reported pressed through careful selection of relevant parameter val- rising permafrost temperatures with accompanying increases ues derived from field information, and simulation results are in active layer depths, when evaluating thermal monitoring then placed in the context of the UNISCALM site as well as data for the 100 m deep Janssonhaugen borehole penetrating other relevant permafrost environments. a bedrock hill in inner Adventdalen over a period of 6 years. For the period 2000–2007, Christiansen and Humlum (2008) used a combined consideration of thermal monitoring data 2 Site description and Circumpolar Active Layer Monitoring (CALM) mea- surements to derive key controlling factors of active layer Adventdalen, located in the central part of Svalbard, is development, which turned out to be mainly air temperature a typical U-shaped valley that dissects a landscape with and solar radiation, at the UNISCALM study site in Advent- peaks, ridges, and plateaus. The valley is partially filled by dalen, central Svalbard. periglacial sediments primarily in the form of colluvial, al- The physics of thermal conduction and latent heat transfer luvial, and aeolian deposits. During about four months of has been the basis of several studies on permafrost dynam- summer, mainly between June and September, the braided ics and active layer processes (Hinzman et al., 1998; Kane et river system of Adventelva discharges into Adventfjorden al., 1991; Shiklomanov and Nelson, 1999; Smith and Rise- (Killingtveit et al., 2003). The tributary streams draining to borough, 2010; Zhang et al., 2008). Studies have also pro- Adventelva have built up large alluvial fans on both sides of ceeded beyond analysis of monitoring data to explore ac- the valley, and several river terraces have been described that tive layer dynamics; Westermann et al. (2010) used ground confine the braided channel system of Adventelva, and can penetrating radar to identify the link between soil

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