Transient Freeze‐Thaw Deformation Responses to the 2018 and 2019 Fires Near Batagaika Megaslump, Northeast Siberia

Yanagiya, Kazuki; Furuya, Masato; Danilov, Petr; Iwahana, Go

doi:10.1029/2022jf006817

Cited by 4 publications

(2 citation statements)

References 50 publications

(89 reference statements)

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“…Anders et al, (2020) performed three TLS measurements over 14 months (June 2015, Aug 2015 and Aug 2016) to observe thaw subsidence of a permafrost area in Northwest Territories, Canada, finding a total change of 1.4 cm; they determined that the TLS measurements were more accurate than those from field-based surveying. Another approach to quantify the effect of seasonal freeze/thaw dynamics on topography is through the use of InSAR remote sensing (de la Barreda-Bautista et al, 2022;Kou et al, 2021;Yanagiya et al, 2023) which can be an effective method to detect the signal of subsidence. Due to its coarser spatial resolution, however, it is likely to underestimate actual heave and subsidence values of smaller isolated features such as palsas.…”

Section: Intra-annual Terrain Dynamics On Palsasmentioning

confidence: 99%

Multitemporal UAV LiDAR detects seasonal heave and subsidence on palsas

Renette,

Olvmo,

Thorsson

et al. 2024

Preprint

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Abstract. In the context of the accelerating impacts of climate change on permafrost landscapes, we use Unpiloted Aerial Vehicle (UAV) LiDAR technology to investigate seasonal terrain changes in palsas – mounds of frozen peat – since other remote sensing methods have struggled to capture the full dynamics of these landforms. We investigated two palsas (4–5 m in height) in Sweden's largest palsa mire complex, where we performed five field campaigns between September 2022 and September 2023 to track intra-annual frost heave and thaw subsidence. Our approach allowed us to create digital terrain models (DTMs) from high density point clouds (>1,000 points/m²) and analyze elevation changes over time. We found that both palsas heaved on average 0.15 m (and up to 0.30 m) from September to April and subsided back to their height from the previous year, or slightly below, over the course of the following summer. At one of the palsas, we observed notable lateral degradation over the study period in a 300 m2 area, with 0.5–2.0 m height loss, likely initiated during the preceding warm and wet summer months. Part of this degradation occurred between September 2022 and April 2023, suggesting that the degradation of these palsas is not limited to the summer months. Our study shows the substantial value of using UAV LiDAR for understanding how permafrost areas are changing. It helps in tracking the ongoing effects of climate change and highlights palsa dynamics that would not be captured by annual measurements alone.

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Section: Intra-annual Terrain Dynamics On Palsasmentioning

confidence: 99%

Multitemporal UAV LiDAR detects seasonal heave and subsidence on palsas

Renette,

Olvmo,

Thorsson

et al. 2024

Preprint

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“…Yanagiya and Furuya (2020) demonstrated the deformation of permafrost surfaces after a 2014 fire in Siberia, where more than 3 million m 3 of permafrost thawed, leading to irreversible subsidence. Yanagiya et al (2023) built on those findings by studying additional geomorphic impacts of 2018 and 2019 fires in Siberia using field measurements and satellite Interferometric Synthetic Aperture Radar (InSAR), finding transient and spatially heterogenous ground deformation in the permafrost terrain that they attributed to fire effects on the active-layer depth. They concluded that the permafrost depth before the fire plays a crucial role in controlling postfire subsidence and thermokarst evolution.…”

Section: Recent Past and Future Evolution Of Fire Patternsmentioning

confidence: 99%

Fire in the Earth System: Introduction to the Special Collection

et al. 2023

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Fire has always been an important component of many ecosystems, but anthropogenic global climate change is now altering fire regimes over much of Earth's land surface, spurring a more urgent need to understand the physical, biological, and chemical processes associated with fire as well as its effects on human societies. In 2020, AGU launched a Special Collection that spanned 10 journals, soliciting papers under the theme “Fire in the Earth System” to encourage state‐of‐the‐art publications in fire‐related science. The completed Special Collection comprises more than 100 papers. Here, we summarize the articles published in this collection, considering them to be grouped into seven themes: paleofire and its ties to climate; evolution of fire patterns in the recent past and the future, including the effects of ongoing climate change; physical (atmospheric) and chemical processes associated with fire; ecosystem effects, including on biogeochemical cycles; physical landscape change after fire and its associated hazards; fire effects on water quality, air quality, and human health; and new methods and technologies applied to fire research.

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