From Drought to Flood: A Water Balance Analysis of the Tuolumne River Basin during Extreme Conditions (2015 – 2017)

Hedrick, A. R.; Marks, Danny; Marshall, Hans‐Peter; McNamara, J. P.; Havens, S.; Trujillo, Ernesto; Sandusky, Micah; Robertson, Mark; Johnson, Micah; Bormann, K. J.; Painter, T. H.

doi:10.1002/hyp.13749

Cited by 16 publications

(15 citation statements)

References 65 publications

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“…The seven water years covered by the library of ALS observations (WY2013 through WY2019) amazingly included (1) abnormally shallow WY2015 that was characterized by a snow volume return period (estimated average time between two seasons with similar snow volume) of over 600 years (Margulis, Cortés, Girotto, Huning, et al, 2016) and was among the shallowest historic snowpacks estimated from tree-ring SWE reconstruction (Belmecheri et al, 2016), and (2) abnormally deep WY2017 with the second-largest 1 April SWE ever recorded in this region (Hedrick et al, 2020). The library of observations allowed us to investigate how extreme years differed from snow distribution patterns from seasons with more typical snowpack.…”

Section: Applications and Future Researchmentioning

confidence: 99%

Inferring Distributed Snow Depth by Leveraging Snow Pattern Repeatability: Investigation Using 47 Lidar Observations in the Tuolumne Watershed, Sierra Nevada, California

Pflug

Lundquist

2020

Water Resources Research

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Snow distribution is controlled by the interaction between local meteorology and static features like topography and vegetation. The resulting spatial pattern of snow in mountainous terrain is often repeatable and can be used to infer snowpack distribution at periods when observations are limited. This study uses a library of airborne lidar surveys (ALS) in California's Tuolumne watershed to analyze snow patterns at extents (1,650 km 2), resolutions (25 m), and temporal scales (47 ALS observations over 7 years) unmatched by previous research. Distributed snow depth was inferred from snow depth observations covering a portion of the domain (< 4%) at a period near peak-snowpack timing and snow distribution patterns from different years. Snow patterns from different years differed as a function of snow extents, variability, and interannual noise (r ¼ 0.30 to 0.90). However, matching criteria like seasonal timing and snow extents were able to identify pairs of snow patterns with increased spatial agreement (median r > 0.84). Distributed snow depth inferred using a strip of observations (<4% coverage), and a well-correlated snow pattern (r≥ 0.90) had a mean absolute error (MAE) of 0.22 m and snow volume error of −6%. Distributed snow depth inferred using patterns of reduced accuracy (r < 0.80) were often too homogeneous, thereby increasing MAE and decreasing the duration of the simulated snowmelt season. This work has applications in water management, where distributed snow depth observations in watersheds with interannual snow pattern repeatability could decrease the extent of observations necessary in future years.

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Section: Applications and Future Researchmentioning

confidence: 99%

Inferring Distributed Snow Depth by Leveraging Snow Pattern Repeatability: Investigation Using 47 Lidar Observations in the Tuolumne Watershed, Sierra Nevada, California

Pflug

Lundquist

2020

Water Resources Research

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“…Snowfall influences both flooding and drought due to its role in regulating the hydrological processes in snow-fed watersheds, with lower than normal winter snow accumulation resulting in a hydrological drought by reducing the water availability later in the hydrological year [80,81]. April-June water resources, which are supplied mainly by snowmelt, and annual water availability, are both positively correlated with the maximum snow thickness in the headwaters of the Irtysh River [33].…”

Section: Snow Droughtsmentioning

confidence: 99%

Opportunities and Challenges Arising from Rapid Cryospheric Changes in the Southern Altai Mountains, China

et al. 2022

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Optimizing the functions and services provided by the mountain cryosphere will maximize its benefits and minimize the negative impacts experienced by the populations that live and work in the cryosphere-fed regions. The high sensitivity of the mountain cryosphere to climate change highlights the importance of evaluating cryospheric changes and any cascading effects if we are to achieve regional sustainable development goals (SDGs). The southern Altai Mountains (SAM), which are located in the arid to semi-arid region of central Asia, are vulnerable to ecological and environmental changes as well as to developing economic activities in northern Xinjiang, China. Furthermore, cryospheric melting in the SAM serves as a major water resource for northeastern Kazakhstan. Here, we systematically investigate historical cryospheric changes and possible trends in the SAM and also discover the opportunities and challenges on regional water resources management arising from these changes. The warming climate and increased solid precipitation have led to inconsistent trends in the mountain cryosphere. For example, mountain glaciers, seasonally frozen ground (SFG), and river ice have followed significant shrinkage trends as evidenced by the accelerated glacier melt, shallowed freezing depth of SFG, and thinned river ice with shorter durations, respectively. In contrast, snow accumulation has increased during the cold season, but the duration of snow cover has remained stable because of the earlier onset of spring melting. The consequently earlier melt has changed the timing of surface runoff and water availability. Greater interannual fluctuations in snow cover have led to more frequent transitions between snow cover hazards (snowstorm and snowmelt flooding) and snow droughts, which pose challenges to hydropower, agriculture, aquatic life, the tail-end lake environment, fisheries, and transboundary water resource management. Increasing the reservoir capacity to regulate interannual water availability and decrease the risk associated with hydrological hazards related to extreme snowmelt may be an important supplement to the regulation and supply of cryospheric functions in a warmer climate.

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“…The ability to fill missing information between point-based snow depth measurement locations has improved our understanding of large-scale snow processes. Data sets from airborne campaigns have been used to improve model capabilities to predict snow precipitation (Behrangi et al, 2018), observe snowfall distributions (Brandt et al, 2020), or improve snow energy balance models (Hedrick et al, 2020). Expanding the number of observed regions with spatially and temporally extensive records can further accelerate our ability to understand snow processes at scale.…”

Section: Expanding Snow Sciencementioning

confidence: 99%

Mapping snow depth and volume at the alpine watershed scale from aerial imagery using Structure from Motion

Meyer

Skiles

Deems

et al. 2021

Preprint

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Abstract. Time series mapping of water held as snow in the mountains at global scales is an unsolved challenge to date. In a few locations, lidar-based airborne campaigns have been used to provide valuable data sets that capture snow distribution in near real-time over multiple seasons. Here, an alternative method is presented to map snow depth and quantify snow volume using aerial images and Structure from Motion (SfM) photogrammetry over an alpine watershed (300 km2). The results were compared to the lidar-derived snow depth measurements from the Airborne Snow Observatory, collected simultaneously. Where snow was mapped by both ASO and SfM, the depths compared well, with a mean difference of 0.01 m, NMAD of 0.22 m, and snow volume agreement (difference 1.26 %). ASO though, mapped a larger snow area relative to SfM, with SfM missing ~14 % of total snow volume as a result. Analyzing the SfM reconstruction errors shows that challenges for photogrammetry remain in vegetated areas, over shallow snow (

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From Drought to Flood: A Water Balance Analysis of the Tuolumne River Basin during Extreme Conditions (2015 – 2017)

Cited by 16 publications

References 65 publications

Inferring Distributed Snow Depth by Leveraging Snow Pattern Repeatability: Investigation Using 47 Lidar Observations in the Tuolumne Watershed, Sierra Nevada, California

Inferring Distributed Snow Depth by Leveraging Snow Pattern Repeatability: Investigation Using 47 Lidar Observations in the Tuolumne Watershed, Sierra Nevada, California

Opportunities and Challenges Arising from Rapid Cryospheric Changes in the Southern Altai Mountains, China

Mapping snow depth and volume at the alpine watershed scale from aerial imagery using Structure from Motion

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