Hazardous Ice Phenomena In Rivers Of The Russian Arctic Zone Under Current Climate Conditions And The Safety Of Water Use

Агафонова, С. А.; Василенко, А. Н.

doi:10.24057/2071-9388-2020-12

Cited by 9 publications

(8 citation statements)

References 10 publications

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Section: Comparison To Previous Resultssupporting

confidence: 90%

“…The same direction of shift was also observed over other SGRs on the Kolyma River (Site ID 1757, 1758) resulting in a shorter duration of river ice cover. The tendency to later freeze-up on the River Yenisey observed by Agafonova and Vasilenko (2020) is consistent with SMOS based results (Site ID 89) as well. Vuglinsky and Valatin (2018) Other papers by Grześ and Ćmielewski (2008) as well as Smith (2000) study apparent trends in river ice events and ice cover changes from databases gathered at the U.S. National Snow and Ice Data Center.…”

Section: Comparison To Previous Resultssupporting

confidence: 89%

“…In the majority of cases, the comparison shows changes consistent with findings reported in multiple scientific papers as summarized with green cells in Table 3. The analyses provided by Agafonova and Vasilenko (2020), Vuglinsky and Valatin (2018), and Cooley and Pavelsky (2016) partially overlap the time period studied in our research. In the first study, the authors used 30-year-long observations (until 2016) from hydrological gages in ) Grześ andĆmielewski (1958-1989) Grześ andĆmielewski (1958-1989) Grześ and Ćmielewski (1958-1989) Smith (1936-1989) Smith (1936-1989) Smith (1936-1989 305 Lena + + + Vuglinsky andValatin (1980-2014) 1050 Mackenzie − Grześ andĆmieleswki (1958-1978) − Cooley andPavelsky (2000-2014) + Grześ andĆmielewski (1958-1978) Grześ andĆmielewski (1958-1978) 1635…”

Section: Comparison To Previous Resultsmentioning

confidence: 99%

“…Since then, data collections as well as access to in‐situ data have been significantly restricted. Agafonova and Vasilenko (2020) provide results from Arctic river ice observations over the period between 1936 and 2016 in Russia but their source dataset is not public. River sections in the high Arctic are monitored by the Water Survey of Canada; only one of their locations (Mackenzie River at Arctic Red River ‐ Site ID 10LC014) is close to a SGR (Site ID 1050) and has observations between 2010 and 2020.…”

Section: Methodsmentioning

confidence: 99%

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Ice Freeze‐Up and Break‐Up in Arctic Rivers Observed With Satellite L‐Band Passive Microwave Data From 2010 to 2020

Podkowa

Kugler

Nghiem

et al. 2023

Water Resources Research

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The timing of ice freeze‐up and break‐up in the Arctic may be responding to climate change. Passive microwave remote sensing is a powerful technique for monitoring this timing. We processed low‐frequency microwave time series from the European Space Agency Soil Moisture and Ocean Salinity (SMOS) mission for a set of 31 satellite gauging reaches (SGRs) above 65°N between 2010 and 2020 to determine timing of freeze‐up and break‐up and annual river ice durations. We found indication of progressive ice cover reduction over more than half of the monitored river reaches, with possibly the fastest rate occurring over northeast Russia. Some rivers in high‐latitude North America experienced a slight increase in ice cover. Across the data set, we observed an average 2.2 days shift toward later ice freeze‐up in autumn and an average 0.6 days shift toward earlier ice break‐up in spring, resulting in an average decrease of 3.4 days in ice duration between 2010 and 2020. River reaches with the longest duration of ice cover appeared to have experienced the fastest rate of decrease. A possible reduction of the time lag between air temperature rise or fall and corresponding river ice break‐up and freeze‐up was also observed. Yet results on variability are carefuly interpreted given the short length of the time series (2010–2020) and the low statistical confidence rates calculated for the decadal tendency. Still outcomes are consistent with increases in global and Arctic surface air temperature. Following these time series over the next decade using passive microwave satellite sensors can monitor ice cover duration in the Arctic and will further determine temporal and regional trends.

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Section: Comparison To Previous Resultssupporting

confidence: 90%

Section: Comparison To Previous Resultssupporting

confidence: 89%

Section: Comparison To Previous Resultsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

See 2 more Smart Citations

Ice Freeze‐Up and Break‐Up in Arctic Rivers Observed With Satellite L‐Band Passive Microwave Data From 2010 to 2020

Podkowa

Kugler

Nghiem

et al. 2023

Water Resources Research

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“…However, in the southern part of the region, the ice thickness is 0.07 to 0.20 m less than that in the north. Climate change has affected river ice in the Canadian Arctic (Prowse et al, 2011a, b) and the European part of Russia (Agafonova and Vasilenko, 2020). Mann-Kendall tests performed on the ice time series with complete records (Polnovat, Gorki and Muzhi; see Table 1) have revealed that ice onset had occurred significantly later (0.05 level) only at the Polnovat station.…”

Section: In Situ Data and Ice Regime At Studied River Reachesmentioning

confidence: 99%

River ice phenology and thickness from satellite altimetry: potential for ice bridge road operation and climate studies

et al. 2021

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Abstract. River ice is a key component of the cryosphere. Satellite monitoring of river ice is a rapidly developing area of scientific enquiry, which has wide-ranging implications for climate, environmental and socioeconomic applications. Spaceborne radar altimetry is widely used for monitoring river water regimes; however, its potential for the observation of river ice processes and properties has not been demonstrated yet. Using Ku-band backscatter measurements from the Jason-2 and Jason-3 satellite missions (2008–2019), we demonstrate the potential of radar altimetry for the retrieval of river ice phenology dates and ice thickness for the first time. The altimetric measurements were determined to be sensitive enough to detect the first appearance of ice and the beginning of thermal breakup on the lower Ob River (Western Siberia). The uncertainties in the retrieval of ice event timing were within the 10 d repeat cycle of Jason-2 and Jason-3 in 88 %–90 % of the cases analysed. The uncertainties in the river ice thickness retrievals made via empirical relations between the satellite backscatter measurements and in situ observations, expressed as the root mean square error (RMSE), were of 0.07–0.18 m. A novel application of radar altimetry is the prediction of ice bridge road operations, which is demonstrated herein. We established that the dates of ferry closing and ice road opening and closing in the city of Salekhard can be predicted with an accuracy (expressed as RMSE) of 3–5 d.

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Freight Transport Management in the Arctic Zone of Russia

Filippova

Власов

Bogumil

2022

The Handbook of the Arctic

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Hazardous Ice Phenomena In Rivers Of The Russian Arctic Zone Under Current Climate Conditions And The Safety Of Water Use

Cited by 9 publications

References 10 publications

Ice Freeze‐Up and Break‐Up in Arctic Rivers Observed With Satellite L‐Band Passive Microwave Data From 2010 to 2020

Ice Freeze‐Up and Break‐Up in Arctic Rivers Observed With Satellite L‐Band Passive Microwave Data From 2010 to 2020

River ice phenology and thickness from satellite altimetry: potential for ice bridge road operation and climate studies

Freight Transport Management in the Arctic Zone of Russia

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