Quantifying the effects of vegetation structure on snow accumulation and ablation in mixed‐conifer forests

Broxton, P. D.; Harpold, Adrian A.; Biederman, Joel A.; Troch, P. A.; Molotch, N. P.; Brooks, P. D.

doi:10.1002/eco.1565

Cited by 141 publications

(239 citation statements)

References 86 publications

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“…Snowmelt provides a critical source of runoff in the mountainous areas of mid‐ to high‐latitudes (Barnett et al, ; Yan et al, ) and sustains summer low flow vital for healthy aquatic habitat. There has been growing recognition over the last century that snow accumulation and ablation in mountain forest environments depend critically on forest structure (Broxton et al, ; Connaughton, ; Moore & McCaughey, ; Pomeroy, Parviainen, Hedstrom, & Gray, ; Varhola, Coops, Weiler, & Moore, ). Despite climate and topographic impacts of varying degrees, many studies found that forested areas, in contrast to open areas, commonly accumulate less snow and thus produce less water available for runoff, due mainly to canopy interception and evapotranspiration of up to 60% of accumulated snow (Cristea, Lundquist, Loheide, Lowry, & Moore, ; Hedstrom & Pomeroy, ; Marks, Kimball, Tingey, & Link, ; McCabe & Clark, ; McCabe, Hay, & Clark, ; Pomeroy et al, ; Regonda, Rajagopalan, Clark, & Pitlick, ; Stednick, ; Stewart, Cayan, & Dettinger, ; Troendle & King, ).…”

Section: Introductionmentioning

confidence: 99%

“…In the Cedar River Watershed located on the western slope of the Cascade Range (characterized by a maritime climate) in the Pacific Northwest, the mean snow duration in a circular gap cut in the forest with a diameter of 20 m (equal to approximately one tree height) was observed to be 1–2 weeks longer than in the adjacent control forest covered by untreated second‐growth forest dominated by western hemlock and Douglas‐fir (Dickerson‐Lange et al, ). These unique benefits of forest gaps have led to recent modelling developments that address the distinct radiation scheme in a forest gap from entirely open or forested areas (Lawler & Link, ; Musselman, Molotch, Margulis, Lehning, & Gustafsson, ), the energy budget at the forest gap floor (Seyednasrollah & Kumar, ), net canopy interception (Moeser, Morsdorf, & Jonas, ; Moeser, Stähli, & Jonas, ), and snow distributions (Broxton et al, ) in the presence of forest gaps.…”

Section: Introductionmentioning

confidence: 99%

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Evaluating the functionality and streamflow impacts of explicitly modelling forest–snow interactions and canopy gaps in a distributed hydrologic model

Sun

Wigmosta

Zhou

et al. 2018

Hydrological Processes

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Many plot‐scale studies have shown that snow‐cover dynamics in forest gaps are distinctly different from those in open and continuously forested areas, and forest gaps have the potential to alter the magnitude and timing of snowmelt. However, the watershed‐level impacts of canopy gap treatment on streamflows are largely unknown. Here, we present the first research that explicitly assesses the impact of canopy gaps on seasonal streamflows and particularly late‐season low flows at the watershed scale. To explicitly model forest–snow interactions in canopy gaps, we made major enhancements to a widely used distributed hydrologic model, distributed hydrology soil vegetation model, with a canopy gap component that represents physical processes of snowpack evolution in the forest gap separately from the surrounding forest on the subgrid scale (within a grid typically 10–150 m). The model predicted snow water equivalent using the enhanced distributed hydrology soil vegetation model showed good agreement (R2 > 0.9) with subhourly snow water equivalent measurements collected from open, forested, and canopy gap sites in Idaho, USA. Compared with the original model that does not account for interactions between gaps and surrounding forest, the enhanced model predicted notably later melt in small‐ to medium‐size canopy gaps (the ratio of gap radius (r) to canopy height (h) ≤ 1.2), and snow melt rates exhibited great sensitivity to changing gap size in medium‐size gaps (0.5 ≤ r/h ≤ 1.2). We demonstrated the watershed‐scale implications of canopy gaps on streamflow in the snow‐dominated Chiwawa watershed, WA, USA. With 24% of the watershed drainage area (about 446 km2) converted to gaps of 60 m diameter, the mean annual 7‐day low flow was increased by 19.4% (i.e., 0.37 m3/s), and the mean monthly 7‐day low flows were increased by 13.5% (i.e., 0.26 m3/s) to 40% (i.e., 1.76 m3/s) from late summer through fall. Lastly, in practical implementation of canopy gaps with the same total gap areas, a greater number of distributed small gaps can have greater potential for longer snow retention than a smaller number of large gaps.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Evaluating the functionality and streamflow impacts of explicitly modelling forest–snow interactions and canopy gaps in a distributed hydrologic model

Sun

Wigmosta

Zhou

et al. 2018

Hydrological Processes

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“…Certain hydrological modeling fields are well poised to utilize high-resolution topography, such as movement of water in urban environments (Fewtrell et al, 2008), in-channel flow modeling (Mandlburger et al, 2009;Legleiter et al, 2011), and hyporheic exchange and ecohydraulics in small streams (e.g., Wheaton et al, 2010b). Finally, high-resolution, three-dimensional lidar measurements of canopy and vegetation structure (Vierling et al, 2008) have direct implications for modeling the surface energy balance (Musselman et al, 2013;Broxton et al, 2014) and evapotranspiration processes (Mitchell et al, 2011) at scales critical to increasing fidelity in physically based models.…”

Section: Advances In Hydrology Using Lidarmentioning

confidence: 99%

“…Lidar has also proven to be instrumental in the verification of model states. For example, lidar data sets have been used to verify physically based models, including landscape evolution models (Pelletier et al, 2014;Pelletier and Perron, 2012;Rengers and Tucker, 2014), aeolian models Pelletier, 2013), physiological models , snowpack energy balance models (Essery et al, 2008, Broxton et al, 2014, and an ecosystem dynamics model (Antonarakis et al, 2014). Simpler, empirical models have also been developed using lidar-derived estimates of soil erosion (Pelletier and Orem, 2014) and snow accumulation and ablation (Varhola et al, 2014).…”

Section: Model Parameterization and Verificationmentioning

confidence: 99%

Laser vision: lidar as a transformative tool to advance critical zone science

Harpold

Marshall

Lyon

et al. 2015

Hydrol. Earth Syst. Sci.

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Abstract. Observation and quantification of the Earth's surface is undergoing a revolutionary change due to the increased spatial resolution and extent afforded by light detection and ranging (lidar) technology. As a consequence, lidar-derived information has led to fundamental discoveries within the individual disciplines of geomorphology, hydrology, and ecology. These disciplines form the cornerstones of critical zone (CZ) science, where researchers study how interactions among the geosphere, hydrosphere, and biosphere shape and maintain the "zone of life", which extends from the top of unweathered bedrock to the top of the vegetation canopy. Fundamental to CZ science is the development of transdisciplinary theories and tools that transcend disciplines and inform other's work, capture new levels of complexity, and create new intellectual outcomes and spaces. Researchers are just beginning to use lidar data sets to answer synergistic, transdisciplinary questions in CZ science, such as how CZ processes co-evolve over long timescales and interact over shorter timescales to create thresholds, shifts in states and fluxes of water, energy, and carbon. The objective of this review is to elucidate the transformative potential of lidar for CZ science to simultaneously allow for quantification of topographic, vegetative, and hydrological processes. A review of 147 peer-reviewed lidar studies highlights a lack of lidar applications for CZ studies as 38 % of the studies were focused in geomorphology, 18 % in hydrology, 32 % in ecology, and the remaining 12 % had an interdisciplinary focus. A handful of exemplar transdisciplinary studies demon- Published by Copernicus Publications on behalf of the European Geosciences Union. 2882 A. A. Harpold et al.: Laser vision: lidar as a transformative toolstrate lidar data sets that are well-integrated with other observations can lead to fundamental advances in CZ science, such as identification of feedbacks between hydrological and ecological processes over hillslope scales and the synergistic co-evolution of landscape-scale CZ structure due to interactions amongst carbon, energy, and water cycles. We propose that using lidar to its full potential will require numerous advances, including new and more powerful open-source processing tools, exploiting new lidar acquisition technologies, and improved integration with physically based models and complementary in situ and remote-sensing observations. We provide a 5-year vision that advocates for the expanded use of lidar data sets and highlights subsequent potential to advance the state of CZ science.

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“…For instance, from a catchment scale to the scale of an individual tree, each element has its own level of variability. A direct relationship exists between snowpack variability and tree-canopy variability (Broxton et al, 2014). Landscape ecologists call this phenomenon a nested hierarchy, in which each level contains the level below.…”

Section: Scalementioning

confidence: 99%