Influence of canopy shading and snow coverage on effective albedo in a snow-dominated evergreen needleleaf forest

The presence of a forest canopy above highly reflective snow results in overall lower surface albedo, even when snow is intercepted by the forest canopy. The effective forest snow albedo (FSA) explains the overall upwelling radiation from the forest relative to the incoming radiation. FSA is strongl...

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Bibliographic Details
Published in:Remote sensing of environment 2018-09, Vol.214, p.48-58
Main Authors: Webster, Clare, Jonas, Tobias
Format: Article
Language:English
Subjects:
Albedo
Alpine forest
Canopies
Canopy cover
Correlation
Current distribution
Flight
Flight paths
Forest canopy
Forest shading
Forests
Interception
Land surface models
Masking
Mathematical models
Observations
Radiation
Radiometers
Shading
Snow
Snow cover
Spatial distribution
Spatial variations
Statistical analysis
Temporal variability
Temporal variations
Unmanned aerial vehicles
Upwelling
Variation
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Summary:The presence of a forest canopy above highly reflective snow results in overall lower surface albedo, even when snow is intercepted by the forest canopy. The effective forest snow albedo (FSA) explains the overall upwelling radiation from the forest relative to the incoming radiation. FSA is strongly influenced by the complex pathways of radiation as it travels through the 3D canopy structure. Current errors in calculations of FSA arise due to uncertainties in how models should treat masking of snow by vegetation. Improvement of distributed models is currently limited by a lack of measurements that demonstrate both spatial and temporal variability over forests. We present above-canopy measurements of winter-time effective forest snow albedo using up- and down-looking radiometers mounted on an octocopter UAV for a total of fifteen flights on eight different days. Ground-view fractions across the flight path were between 0.12 and 0.81. Correlations between FSA and both ground-view fraction and maximum canopy height were statistically significant during 14 out of 15 flights, but correlation strength varied between flights as a function of solar angle and snow cover. Measured effective albedo across the flight path differed by up to 0.33 during snow-on canopy conditions. A subsequent comparison between maximum interception and no interception showed effective albedo differed by up 0.27. A similar variation (0.26) in effective FSA was measured during low (44°) and high (67°) solar zenith angles. This study therefore demonstrates that temporal and spatial variations in effective albedo caused by canopy shading of the snow surface are therefore as important as temporal variations caused by interception of snow by the canopy. Calculation of effective albedo of forested areas requires careful consideration of canopy height, canopy coverage, solar angle and interception coverage. The results of this study should be used to inform snow albedo and canopy structure parametrizations in local and larger scale land surface models. •Effective forest snow albedo (EFSA) measured using up/down-looking radiometers on UAV.•Data allowed detailed analysis of the consequences of canopy structure on EFSA.•Both ground-view fraction and maximum canopy height affected EFSA considerably.•The solar angle influenced EFSA via its effect on the extent of shadows on the snow.•The effect of canopy shading was as relevant as the effect of snow in the canopy.
ISSN:0034-4257
1879-0704
DOI:10.1016/j.rse.2018.05.023