255 research outputs found
Morphological dynamics of an englacial channel
Despite an interest in the hydraulic functioning of supraglacial and englacial
channels over the last 4 decades, the processes and forms of such
ice-bounded streams have remained poorly documented. Recent glaciological
research has demonstrated the potential significance of so-called
"cut-and-closure" streams, where englacial or subglacial flow paths are
created from the long-term incision of supraglacial channels. These flow paths
are reported to exhibit step-pool morphology, comprising knickpoints and/or
knickzones, exaggerated in dimensions in comparison to supraglacial channels.
However, little is known of the development of such channels' morphology.
Here, we examine the spatial organisation of step pools and the upstream
migration of steps, many of which form knickzones, with repeated surveys over
a 10-year period in an englacial conduit in cold-based Austre
Brøggerbreen, Svalbard. The observations show upstream step recession to
be the dominant process for channel evolution. This is paralleled by an
increase in average step height and conduit gradient over time.
Characteristic channel-reach types and step-riser forms are consistently
observed in each of the morphological surveys reported. We suggest that the
formation of steps has a hydrodynamic origin, where step-pool geometry is
more efficient for energy dissipation than meanders. The englacial channel
system is one in rapid transition towards a quasi-equilibrium form within a
decadal timescale. The evolution and recession of knickzones reported here
result in the formation of a 37 m deep moulin shaft, suggesting that over
time an incising supraglacial channel may evolve towards an englacial channel
form exhibiting a stable end-point characterised by a singular vertical
descent, which potentially can reach the glacier bed. This challenges the
prevailing notions that crevasses or hydrofractures are needed to form deep
moulins. Our observations highlight the need to further examine the
adjustment processes in cut-and-closure channels to better understand their
coupling to supraglacial meltwater sources and potential significance in
cold-based glacier hydrology and ice dynamics
スバールバル諸島北西部の氷河におけるクリオコナイトの特性の空間分布
第6回極域科学シンポジウム[OM] 極域気水圏11月16日(月) 国立極地研究所1階交流アトリウ
Cryoconite:The dark biological secret of the cryosphere
Cryoconite is granular sediment found on glacier surfaces comprising both mineral and biological material. Despite long having been recognised as an important glaciological and biological phenomenon cryoconite remains relatively poorly understood. Here, we appraise the literature on cryoconite for the first time, with the aim of synthesising and evaluating current knowledge to direct future investigations. We review the properties of cryoconite, the environments in which it is found, the biology and biogeochemistry of cryoconite, and its interactions with climate and anthropogenic pollutants. We generally focus upon cryoconite in the Arctic in summer, with Antarctic and lower latitude settings examined individually. We then compare the current state-of-the-science with that at the turn of the twentieth century, and suggest directions for future research including specific recommendations for studies at a range of spatial scales and a framework for integrating these into a more holistic understanding of cryoconite and its role in the cryosphere
Measuring glacier surface roughness using plot-scale, close-range digital photogrammetry
Glacier roughness at sub-metre scales is an important control on the ice surface energy balance and has implications for scattering energy measured by remote-sensing instruments. Ice surface roughness is dynamic as a consequence of spatial and temporal variation in ablation. To date, studies relying on singular and/or spatially discrete two-dimensional profiles to describe ice surface roughness have failed to resolve common patterns or causes of variation in glacier surface morphology. Here we demonstrate the potential of close-range digital photogrammetry as a rapid and cost-effective method to retrieve three-dimensional data detailing plot-scale supraglacial topography. The photogrammetric approach here employed a calibrated, consumer-grade 5 Mpix digital camera repeatedly imaging a plotscale (≤25m2) ice surface area on Midtre Lovénbreen, Svalbard. From stereo-pair images, digital surface models (DSMs) with sub-centimetre horizontal resolution and 3mm vertical precision were achieved at plot scales ≤4m2. Extraction of roughness metrics including estimates of aerodynamic roughness length (z0) was readily achievable, and temporal variations in the glacier surface topography were captured. Close-range photogrammetry, with appropriate camera calibration and image acquisition geometry, is shown to be a robust method to record sub-centimetre variations in ablating ice topography. While the DSM plot area may be limited through use of stereo-pair images and issues of obliquity, emerging photogrammetric packages are likely to overcome such limitations
Seasonally stable temperature gradients through supraglacial debris in the Everest region of Nepal, Central Himalaya
Rock debris covers about 30% of glacier ablation areas in the Central Himalaya and modifies the impact of atmospheric conditions on mass balance. The thermal properties of supraglacial debris are diurnally variable but remain poorly constrained for monsoon-influenced glaciers over the timescale of the ablation season. We measured vertical debris profile temperatures at 12 sites on four glaciers in the Everest region with debris thickness ranging from 0.08–2.8 m. Typically, the length of the ice ablation season beneath supraglacial debris was 160 days (15 May to 22 October)—a month longer than the monsoon season. Debris temperature gradients were approximately linear (r2 > 0.83), measured as –40°C m–1 where debris was up to 0.1 m thick, –20°C m–1 for debris 0.1–0.5 m thick, and –4°C m–1 for debris greater than 0.5 m thick. Our results demonstrate that the influence of supraglacial debris on the temperature of the underlying ice surface, and therefore melt, is stable at a seasonal timescale and can be estimated from near-surface temperature. These results have the potential to greatly improve the representation of ablation in calculations of debris-covered glacier mass balance and projections of their response to climate change.Peer reviewe
Changes in glacier surface cover on Baltoro glacier, Karakoram, north Pakistan, 2001–2012
The presence of supraglacial debris on glaciers in the Himalaya-Karakoram affects the ablation rate of these glaciers and their response to climatic change. To understand how supraglacial debris distribution and associated surface features vary spatially and temporally, geomorphological mapping was undertaken on Baltoro Glacier, Karakoram, for three time-separated images between 2001–2012. Debris is supplied to the glacier system through frequent but small landslides at the glacier margin that form lateral and medial moraines and less frequent but higher volume rockfall events which are more lobate and often discontinuous in form. Debris on the glacier surface is identified as a series of distinct lithological units which merge downglacier of the convergence area between the Godwin-Austen and Baltoro South tributary glaciers. Debris distribution varies as a result of complex interaction between tributary glaciers and the main glacier tongue, complicated further by surge events on some tributary glaciers. Glacier flow dynamics mainly controls the evolution of a supraglacial debris layer. Identifying such spatial variability in debris rock type and temporal variability in debris distribution has implications for glacier ablation rate, affecting glacier surface energy balance. Accordingly, spatial and temporal variation in supraglacial debris should be considered when determining mass balance for these glaciers through time
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