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Evaluation of forest snow processes models (SnowMIP2) (2009)

Rutter, Nick ; Essery, Richard ; Pomeroy, John ; [et al.]

American Geophysical Union

In: Journal of Geophysical Research. 2009; 114(D6): D06111. Published 2009 Mar 25. doi: 10.1029/2008jd011063.

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Publication Date: 2009-03-25

Print ISSN: 0148-0227

Electronic ISSN: 2156-2202

Topics: Geosciences

Published by American Geophysical Union

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Estimating sub-canopy shortwave irradiance to melting snow on forested slopes (2007)

Ellis, Chad R. ; Pomeroy, John W.

Wiley

In: Hydrological Processes. 2007; 21(19): 2581-2593. Published 2007 Jan 01. doi: 10.1002/hyp.6794.

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Publication Date: 2007-01-01

Description: Estimates of shortwave irradiance energy beneath needle-leaf forests over complex terrain are needed to drive energy balance snowmelt models and to evaluate the potential hydrological impacts of forest-cover change in mountain regions. This paper outlines and evaluates a physically-based model designed to estimate sub-canopy shortwave irradiance to snowcover under needle-leaf forest-cover with respect to surface slope and azimuth. Transmission of above-canopy irradiance was estimated using forest-surveys and hemispherical photographs to determine the fractions of forest-cover occupied by non-transmitting trunks, partially-transmitting crowns and fully-transmitting gaps with respect to above-canopy diffuse and direct beam shortwave irradiance. Simulations were conducted for continuous, uniform lodgepole pine forests on level site and a north facing slope and a discontinuous, non-uniform forest on a southeast facing slope during snowmelt at the Marmot Creek Research Basin, Alberta, Canada. Mean observed daily transmissivity values of inadiance were 0.09 at the north-facing forest, 0.21 at the level forest and 0.36 at the southeast-facing forest. Modelled and observed results indicate that potential snowmelt energy from sub-canopy shortwave irradiance is likely to exhibit the greatest variation with change in cloudiness and forest-cover density under south-facing forests and the least variation under north-facing forests. Comparisons of simulations to observations indicate that the model can explain much of the difference in daily shortwave transmission amongst sites, performing relatively poorest at the north-facing forest where fluxes were small and relatively best at the south-east facing forest where fluxes were large. However, simulation errors in terms of absolute irradiance were greatest at the southeast-facing forest, having a root mean square error (RMSE) 0.64 MJ m-2 d-1 compared to 0.44 MJ m-2 d-1 at the level forest and 0.27 MJ m-2 d-1 at the north-facing forest. Copyright © 2007 John Wiley & Sons, Ltd.

Print ISSN: 0885-6087

Electronic ISSN: 1099-1085

Topics: Architecture, Civil Engineering, Surveying , Geography

Published by Wiley

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Sensitivity of snowmelt hydrology in Marmot Creek, Alberta, to forest cover disturbance (2012)

Pomeroy, John ; Fang, Xing ; Ellis, Chad

Wiley

In: Hydrological Processes. 2012; 26(12): 1892-1905. Published 2012 Jun 15. doi: 10.1002/hyp.9248.

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Publication Date: 2012-06-15

Description: A model including slope effects on snow redistribution, interception and energetics was developed using the Cold Regions Hydrological Model platform, parameterized with minimal calibration and manipulated to simulate the impacts of forest disturbance on mountain hydrology. A total of 40 forest disturbance scenarios were compared with the current land cover for four simulation years. Disturbance scenarios ranged from the impact of pine beetle kill of lodgepole pine to clear-cutting of north- or south-facing slopes, forest fire and salvage logging. Pine beetle impacts were small in all cases with increases in snowmelt volume of less than 10% and streamflow volume of less than 2%. This small impact is attributed to the low and relatively dry elevations of lodgepole pine forests in the basin. Forest disturbances due to fire and clear-cutting affected much larger areas and higher elevations of the basin and were generally more than twice as effective as pine beetle in increasing snowmelt or streamflow. For complete forest cover removal by burning and salvage logging, a 45% increase in snowmelt volume was simulated; however, this only translated into a 5% increase in spring and summer streamflow volume. Forest burning with the retention of standing burned trunks was the most effective forest cover treatment for increasing streamflow (up to 8%) because of its minimizing of winter snow sublimation losses from interception and blowing snow. However, increases in streamflow volumes were almost entirely due to reductions in intercepted snow sublimation with decreasing canopy coverage. Peak daily streamflow discharges responded more strongly to forest cover disturbance than did seasonal streamflow volumes, with increases of almost 25% in peak streamflow from the removal of forest canopy by fire and the retention of standing burned trunks. Peak flow was most effectively increased by forest removal on south-facing slopes and level sites. © 2012 John Wiley & Sons, Ltd.

Print ISSN: 0885-6087

Electronic ISSN: 1099-1085

Topics: Architecture, Civil Engineering, Surveying , Geography

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Modelling longwave radiation to snow beneath forest canopies using hemispherical photography or linear regression (2008)

Essery, Richard ; Pomeroy, John ; Ellis, Chad ; [et al.]

Wiley

In: Hydrological Processes. 2008; 22(15): 2788-2800. Published 2008 Jul 15. doi: 10.1002/hyp.6930.

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Publication Date: 2008-07-15

Description: Forest canopies reduce shortwave radiation and increase longwave radiation reaching the underlying surface, compared with open areas, and thus influence rates at which forest snowpacks melt. The sub-canopy radiative environment can be highly heterogeneous, with temporal persistence depending on canopy structure and differing for shortwave and longwave fluxes, and this influences the rate at which snow-free ground emerges during snowmelt. Arrays of radiometers have been used to measure spatial variability in forest radiation, but such instruments are expensive and require regular attention in snowy environments. Hemispherical photography allows rapid collection of canopy structure data, and many software packages have been developed for modelling transmission of shortwave radiation using hemispherical photographs, but modelling of longwave radiation has received much less attention. Results are used here from radiometers located beneath lodgepole pine stands of varying density at the Marmot Creek Research Basin in Alberta, Canada. A simple model using sky view calculated from hemispherical photographs to weight longwave emissions from the canopy, calculated using measured air temperature as a proxy for canopy temperature, and measured above-canopy longwave radiation is found to give good estimates for spatial averages of sub-canopy longwave radiation, although standard deviations are generally underestimated. If above-canopy longwave radiation is parametrized as a function of air temperature and humidity rather than measured, good results are still obtained for daily and longer averages of sub-canopy longwave radiation. A multiple linear regression model using measurements of above-canopy shortwave radiation to estimate daytime canopy heating gives better results in comparison with individual radiometers. Copyright © 2008 John Wiley & Sons, Ltd.

Print ISSN: 0885-6087

Electronic ISSN: 1099-1085

Topics: Architecture, Civil Engineering, Surveying , Geography

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The impact of coniferous forest temperature on incoming longwave radiation to melting snow (2009)

Pomeroy, John W. ; Marks, Danny ; Link, Tim ; [et al.]

Wiley

In: Hydrological Processes. 2009; 23(17): 2513-2525. Published 2009 Aug 15. doi: 10.1002/hyp.7325.

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Publication Date: 2009-08-15

Description: Measurements were conducted in coniferous forests of differing density, insolation and latitude to test whether air temperatures are suitable surrogates for canopy temperature in estimating sub-canopy longwave irradiance to snow. Air temperature generally was a good representation of canopy radiative temperature under conditions of low insolation. However during high insolation, needle and branch temperatures were well estimated by air temperature only in relatively dense canopies and exceeded air temperatures elsewhere. Tree trunks exceeded air temperatures in all canopies during high insolation, with the relatively hottest trunks associated with direct interception of sunlight, sparse canopy cover and dead trees. The exitance of longwave radiation from these relatively warm canopies exceeded that calculated assuming canopy temperature was equal to air temperature. This enhancement was strongly related to the extinction of shortwave radiation by the canopy. Estimates of sub-canopy longwave irradiance using either two-energy source or two thermal regime approaches to evaluate the contribution of canopy longwave exitance performed better than did estimates that used only air temperature and sky view. However, there was little evidence that such corrections are necessary under cloudy or low solar insolation conditions. The longwave enhancement effect due to shortwave extinction was important to sub-canopy longwave irradiance to snow during clear, sunlit conditions. Longwave enhancement increased with increasing solar elevation angle and decreasing air temperature. Its relative importance to longwave irradiance to snow was insensitive to canopy density. As errors from ignoring enhanced longwave contributions from the canopy accumulate over the winter season, it is important for snow energy balance computations to include the enhancement in order to better calculate snow internal energy and therefore the timing and magnitude of snowmelt and sublimation. Copyright © 2009 John Wiley & Sons, Ltd.

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Electronic ISSN: 1099-1085

Topics: Architecture, Civil Engineering, Surveying , Geography

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Spatial Variability of Shortwave Irradiance for Snowmelt in Forests (2008)

Pomeroy, John ; Ellis, Chad ; Rowlands, Aled ; [et al.]

American Meteorological Society

In: Journal of Hydrometeorology. 2008; 9(6): 1482-1490. Published 2008 Dec 01. doi: 10.1175/2008jhm867.1.

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Publication Date: 2008-12-01

Description: The spatial variation of melt energy can influence snow cover depletion rates and in turn be influenced by the spatial variability of shortwave irradiance to snow. The spatial variability of shortwave irradiance during melt under uniform and discontinuous evergreen canopies at a U.S. Rocky Mountains site was measured, analyzed, and then compared to observations from mountain and boreal forests in Canada. All observations used arrays of pyranometers randomly spaced under evergreen canopies of varying structure and latitude. The spatial variability of irradiance for both overcast and clear conditions declined dramatically, as the sample averaging interval increased from minutes to 1 day. At daily averaging intervals, there was little influence of cloudiness on the variability of subcanopy irradiance; instead, it was dominated by stand structure. The spatial variability of irradiance on daily intervals was higher for the discontinuous canopies, but it did not scale reliably with canopy sky view. The spatial variation in irradiance resulted in a coefficient of variation of melt energy of 0.23 for the set of U.S. and Canadian stands. This variability in melt energy smoothed the snow-covered area depletion curve in a distributed melt simulation, thereby lengthening the duration of melt by 20%. This is consistent with observed natural snow cover depletion curves and shows that variations in melt energy and snow accumulation can influence snow-covered area depletion under forest canopies.

Print ISSN: 1525-755X

Electronic ISSN: 1525-7541

Topics: Geography , Geosciences , Physics