Increasing Alaskan river discharge during the cold season is driven by recent warming

Blaskey, Dylan; Koch, Joshua C.; Gooseff, M. N.; Newman, Andrew J.; Cheng, Yifan; O'Donnell, Jonathan; Musselman, K. N.

doi:10.1088/1748-9326/acb661

Cited by 9 publications

(7 citation statements)

References 55 publications

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“…Mean annual and seasonal air temperatures are increasing statewide with the largest warming signal detected in winter (Bieniek et al, 2014;Stafford et al, 2000). In response to warming, we have observed a large increase in the extent of permafrost degradation (Jorgenson et al, 2006;Lawrence & Slater, 2005;Osterkamp & Romanovsky, 1999;Saito et al, 2020), a shifted annual snow cycle and earlier snowmelt (Cox et al, 2017;Musselman et al, 2021;Stone et al, 2002), as well as increasing cold season discharge in Alaskan rivers (Blaskey et al, 2023;Gudmundsson et al, 2019). These hydroclimatic changes are deteriorating the quality of river ice roads and corresponding transportation safety, affecting terrestrial and aquatic ecosystems, and disproportionately increasing threats to Indigenous Alaskans, especially those who practice subsistence living (Knoll et al, 2019;McNeeley & Shulski, 2011).…”

Section: Introductionmentioning

confidence: 72%

Coupled high-resolution land-atmosphere modeling for hydroclimate and terrestrial hydrology in Alaska and the Yukon River Basin (1990-2021)

Cheng,

Craig,

Musselman

et al. 2024

Preprint

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Hydroclimate and terrestrial hydrology greatly influence the local community, ecosystem, and economy in Alaska and Yukon River Basin. A high-resolution re-simulation of the historical climate in Alaska can provide an important benchmark for climate change studies. In this study, we utilized the Regional Arctic Systems Model (RASM) and conducted coupled land-atmosphere modeling for Alaska and Yukon River Basin at 4-km grid spacing. In RASM, the land model was replaced with the Community Terrestrial Systems Model (CTSM) given its comprehensive process representations for cold regions. The microphysics schemes in the Weather Research and Forecast (WRF) atmospheric model were manually tuned for optimal model performance. This study aims to maintain good model performance for both hydroclimate and terrestrial hydrology, especially streamflow, which was rarely a priority in coupled models. Therefore, we implemented a strategy of iterative testing and re-optimization of CTSM. A multi-decadal climate dataset (1990-2021) was generated using RASM with optimized land parameters and manually tuned WRF microphysics. When evaluated against multiple observational datasets, this dataset well captures the climate statistics and spatial distributions for five key weather variables and hydrologic fluxes, including precipitation, air temperature, snow fraction, evaporation-to-precipitation ratios, and streamflow. The simulated precipitation shows wet bias during the spring season and simulated air temperatures exhibit dampened seasonality with warm biases in winter and cold biases in summer. We used transfer entropy to investigate the discrepancy in connectivity of hydrologic fluxes between the offline CTSM and coupled models, which contributed to their discrepancy in streamflow simulations.

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Section: Introductionmentioning

confidence: 72%

Coupled high-resolution land-atmosphere modeling for hydroclimate and terrestrial hydrology in Alaska and the Yukon River Basin (1990-2021)

Cheng,

Craig,

Musselman

et al. 2024

Preprint

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“…Despite rapid changes to high‐latitude ecosystems evident in changing river chemistry, research efforts in Arctic rivers have lagged behind those in temperate regions (Laudon et al., 2017). The spring snowmelt and mid‐season storm events are predicted to become more intense (Blaskey et al., 2023; Dou et al., 2022), resulting in seasonal and interannual changes in the magnitude of C and N transported from Arctic headwaters. In recent years, optical sensors have provided a useful tool to help quantify additional solutes of interest (Burns et al., 2019; Crawford et al., 2015; Pellerin et al., 2016; Rode et al., 2016).…”

Section: Discussionmentioning

confidence: 99%

Hydrology Controls Dissolved Organic Carbon and Nitrogen Export and Post‐Storm Recovery in Two Arctic Headwaters

Shogren,

Zarnetske,

Abbott

et al. 2024

JGR Biogeosciences

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Climate change is rapidly altering hydrological processes and consequently the structure and functioning of Arctic ecosystems. Predicting how these alterations will shape biogeochemical responses in rivers remains a major challenge. We measured [C]arbon and [N]itrogen concentrations continuously from two Arctic watersheds capturing a wide range of flow conditions to assess understudied event‐scale C and N concentration‐discharge (C‐Q) behavior and post‐event recovery of stoichiometric conditions. The watersheds represent low‐gradient, tundra landscapes typical of the eastern Brooks Range on the North Slope of Alaska and are part of the Arctic Long‐Term Ecological Research sites: the Kuparuk River and Oksrukuyik Creek. In both watersheds, we deployed high‐frequency optical sensors to measure dissolved organic carbon (DOC), nitrate (), and total dissolved nitrogen (TDN) for five consecutive thaw seasons (2017–2021). Our analyses revealed a lag in DOC: stoichiometric recovery after a hydrologic perturbation: while DOC was consistently elevated after high flows, diluted during rainfall events and consequently, recovery in post‐event concentration was delayed. Conversely, the co‐enrichment of TDN at high flows, even in watersheds with relatively high N‐demand, represents a potential “leak” of hydrologically available organic N to downstream ecosystems. Our use of high‐frequency, long‐term optical sensors provides an improved method to estimate carbon and nutrient budgets and stoichiometric recovery behavior across event and seasonal timescales, enabling new insights and conceptualizations of a changing Arctic, such as assessing ecosystem disturbance and recovery across multiple timescales.

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“…Although the specific effects on river corridor dynamics is uncertain, the changes are likely to lead to warmer river water temperatures, which implies permafrost melt, active layer thickening, and talik deepening, all of which increases the volume of subsurface liquid water available to discharge to the surface. Warming river temperatures and increasing winter river discharge are ongoing throughout Alaska and especially on the North Slope (Blaskey et al, 2023). Many springs in northern Alaska have not shown a temperature increase between 1975 and 2021 (Koch et al, 2024), suggesting that the source of water to the aufeis fields may not warm in the near future.…”

Section: Effect Of Climate Changementioning

confidence: 99%

Seasonal and decadal subsurface thaw dynamics of an Aufeis feature investigated through numerical simulations

Lainis,

Neupauer,

Koch

et al. 2024

Hydrological Processes

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Aufeis (also known as icings) are large sheet‐like masses of layered ice that form in river channels in arctic environments in the winter as groundwater discharges to the land surface and subsequently freezes. Aufeis are important sources of water for Arctic river ecosystems, bolstering late summer river discharge and providing habitat for caribou escaping insect harassment. The aim of this research is to use numerical simulations to evaluate a conceptual model of subsurface hydrogeothermal conditions that can lead to the formation of aufeis. We used a conceptual model based on geophysical data from the Kuparuk aufeis field on the North Slope of Alaska to develop a two‐dimensional heterogeneous vertical profile model of groundwater flow, heat transport, and freeze/thaw dynamics. Modelling results showed that groundwater can flow to the land surface through subvertical high permeability pathways during winter months when the lower permeability soils near the land surface are frozen. The groundwater discharge can freeze on the surface, contributing to aufeis formation throughout the winter. We performed sensitivity analyses on subsurface properties and surface temperature and found that aufeis formation is most sensitive to the volume of unfrozen water available in the subsurface and the rate at which the subsurface water travels to the land surface. Although a trend of warming air temperatures will lead to a greater volume of unfrozen subsurface water, the aufeis volume can be reduced under warming conditions if the period of time for which air temperatures are below freezing is reduced.

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Increasing Alaskan river discharge during the cold season is driven by recent warming

Cited by 9 publications

References 55 publications

Coupled high-resolution land-atmosphere modeling for hydroclimate and terrestrial hydrology in Alaska and the Yukon River Basin (1990-2021)

Coupled high-resolution land-atmosphere modeling for hydroclimate and terrestrial hydrology in Alaska and the Yukon River Basin (1990-2021)

Hydrology Controls Dissolved Organic Carbon and Nitrogen Export and Post‐Storm Recovery in Two Arctic Headwaters

Seasonal and decadal subsurface thaw dynamics of an Aufeis feature investigated through numerical simulations

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