TY - JOUR
T1 - Time‐lapse photogrammetry reveals hydrological controls of fine‐scale High‐Arctic glacier surface roughness evolution
AU - Irvine-Fynn, Tristram D.L.
AU - Holt, Tom O.
AU - James, Timothy D.
AU - Smith, Mark W.
AU - Rutter, Nick
AU - Porter, Philip R.
AU - Hodson, Andrew J.
N1 - Funding Information:
TDLI-F acknowledges The Leverhulme Trust (Grant: RF-2018-584/4) and The Climate Change Consortium of Wales (C3W). The University Centre in Svalbard (UNIS) is thanked for the logistical support of fieldwork. AJH and TDLI-F acknowledge The Royal Geographical Society – Peter Fleming Award, a National Geographic Research and Exploration grant and Store Norske Spitsbergen Kulkompani AS for the help in establishing the monitoring at Foxfonna. Support from TerraDat with Topcon's Image Master Pro was gratefully received by TDJ. TDLI-F thanks Jim Chandler for a late-night conversation at an ‘Arolla project reunion’ well over a decade ago suggesting that ‘if there was enough texture maybe one commercial grade camera and some photogrammetry might reveal the topographic dynamics of an ice surface’. How the field developed! Pete Bunting is thanked for help adapting the energy balance model code, and Morgan Jones and Hywel Griffiths commented on earlier versions of the manuscript. Two anonymous reviewers are thanked for constructive feedback that improved the clarity of the article.
Publisher Copyright:
© 2022 The Authors. Earth Surface Processes and Landforms published by John Wiley & Sons Ltd.
PY - 2022/5/13
Y1 - 2022/5/13
N2 - In a warming Arctic, as glacier snowlines rise, short- to medium-term increases in seasonal bare-ice extent are forecast for the next few decades. These changes will enhance the importance of turbulent energy fluxes for surface ablation and glacier mass balance. Turbulent energy exchanges at the ice surface are conditioned by its topography, or roughness, which has been hypothesized to be controlled by supraglacial hydrology at the glacier scale. However, current understanding of the dynamics in surface topography, and the role of drainage development, remains incomplete, particularly for the transition between seasonal snow cover and well-developed, weathered bare-ice. Using time-lapse photogrammetry, we report a daily timeseries of fine (millimetre)-scale supraglacial topography at a 2 m2 plot on the Lower Foxfonna glacier, Svalbard, over two 9-day periods in 2011. We show traditional kernel-based morphometric descriptions of roughness were ineffective in describing temporal change, but indicated fine-scale albedo feedbacks at depths of ~60 mm contributed to conditioning surface topography. We found profile-based and two-dimensional estimates of roughness revealed temporal change, and the aerodynamic roughness parameter, z0, showed a 22–32% decrease from ~1 mm following the exposure of bare-ice, and a subsequent 72–77% increase. Using geostatistical techniques, we identified ‘hole effect’ properties in the surface elevation semivariograms, and demonstrated that hydrological drivers control the plot-scale topography: degradation of superimposed ice reduces roughness while the inception of braided rills initiates a subsequent development and amplification of topography. Our study presents an analytical framework for future studies that interrogate the coupling between ice surface roughness and hydro-meteorological variables and seek to improve parameterizations of topographically evolving bare-ice areas.
AB - In a warming Arctic, as glacier snowlines rise, short- to medium-term increases in seasonal bare-ice extent are forecast for the next few decades. These changes will enhance the importance of turbulent energy fluxes for surface ablation and glacier mass balance. Turbulent energy exchanges at the ice surface are conditioned by its topography, or roughness, which has been hypothesized to be controlled by supraglacial hydrology at the glacier scale. However, current understanding of the dynamics in surface topography, and the role of drainage development, remains incomplete, particularly for the transition between seasonal snow cover and well-developed, weathered bare-ice. Using time-lapse photogrammetry, we report a daily timeseries of fine (millimetre)-scale supraglacial topography at a 2 m2 plot on the Lower Foxfonna glacier, Svalbard, over two 9-day periods in 2011. We show traditional kernel-based morphometric descriptions of roughness were ineffective in describing temporal change, but indicated fine-scale albedo feedbacks at depths of ~60 mm contributed to conditioning surface topography. We found profile-based and two-dimensional estimates of roughness revealed temporal change, and the aerodynamic roughness parameter, z0, showed a 22–32% decrease from ~1 mm following the exposure of bare-ice, and a subsequent 72–77% increase. Using geostatistical techniques, we identified ‘hole effect’ properties in the surface elevation semivariograms, and demonstrated that hydrological drivers control the plot-scale topography: degradation of superimposed ice reduces roughness while the inception of braided rills initiates a subsequent development and amplification of topography. Our study presents an analytical framework for future studies that interrogate the coupling between ice surface roughness and hydro-meteorological variables and seek to improve parameterizations of topographically evolving bare-ice areas.
KW - glacier surface
KW - hydrology
KW - photogrammetry
KW - roughness
KW - semivariance
UR - http://www.scopus.com/inward/record.url?scp=85125083870&partnerID=8YFLogxK
U2 - 10.1002/esp.5339
DO - 10.1002/esp.5339
M3 - Article
AN - SCOPUS:85125083870
SN - 0197-9337
VL - 47
SP - 1635
EP - 1652
JO - Earth Surface Processes and Landforms
JF - Earth Surface Processes and Landforms
IS - 6
ER -