Adaptation Methods for Transportation Infrastructure Built on Degrading Permafrost

Doré, Guy; Niu, Fujun; Brooks, Heather

doi:10.1002/ppp.1919

Cited by 142 publications

(59 citation statements)

References 39 publications

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“…Furthermore, permafrost thaw can lead to ground movement via thaw settlement, and changed geotechnical characteristics via ground-ice melt. This is important because it can lead to problems with infrastructure built in permafrost environments, which requires special attention during planning, construction, and maintenance (Doré et al 2016;Bommer et al 2010).…”

Section: Observed Changementioning

confidence: 99%

Status and Change of the Cryosphere in the Extended Hindu Kush Himalaya Region

Bolch

Shea

Liu

et al. 2019

The Hindu Kush Himalaya Assessment

219

175

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Section: Observed Changementioning

confidence: 99%

Status and Change of the Cryosphere in the Extended Hindu Kush Himalaya Region

Bolch

Shea

Liu

et al. 2019

The Hindu Kush Himalaya Assessment

219

175

View full text Add to dashboard Cite

“…The temperatures within a road embankment's sub‐base (i.e., a layer of fill material) and subgrade (i.e., native material under an embankment) are a function of air temperature, atmospheric radiation, wind convection, and heat conduction through the embankment material (Dumais & Doré, ; Hall, Dehdezi, Dawson, Grenfell, & Isola, ; Zhang, Wu, Liu, & Gao, ). The thermal regime of infrastructure can be modified and cooled by mitigation techniques used in or on the embankment (Chen, Yu, Yi, Hu, & Liu, ; Doré, Niu, & Brooks, ; Goering & Kumar, ; Lai, Zhang, Zhang, & Mi, ). Water infiltration and subsurface water flow through and under an embankment can also alter the thermal regime of roadways (de Grandpré, Fortier, & Stephani, ; Fortier et al, ; Zottola, Darrow, Daanen, Fortier, & Grandpré, ).…”

Section: Introductionmentioning

confidence: 99%

“…2017). The thermal regime of infrastructure can be modified and cooled by mitigation techniques used in or on the embankment (Chen, Yu, Yi, Hu, & Liu, 2018;Doré, Niu, & Brooks, 2016;Goering & Kumar, 1996;Lai, Zhang, Zhang, & Mi, 2003). Water infiltration and subsurface water flow through and under an embankment can also alter the thermal regime of roadways (de Grandpré, Fortier, & Stephani, 2012;Fortier et al, 2016;Zottola, Darrow, Daanen, Fortier, & Grandpré, 2012).…”

mentioning

confidence: 99%

Impact of heat advection on the thermal regime of roads built on permafrost

Chen

Fortier

McKenzie

et al. 2020

Hydrological Processes

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In northern regions, transportation infrastructure can experience severe structural damages due to permafrost degradation. Water infiltration and subsurface water flow under an embankment affect the energy balance of roadways and underlying permafrost. However, the quantification of the processes controlling these changes and a detailed investigation of their thermal impacts remain largely unknown due to a lack of available long‐term embankment temperature data in permafrost regions. Here, we report observations of heat advection linked to surface water infiltration and subsurface flow based on a 9‐year (from 2009 to 2017) thermal monitoring at an experimental road test site built on ice‐rich permafrost conditions in southwestern Yukon, Canada. Our results show that snowmelt water infiltration in the spring rapidly increases temperature in the upper portion of the embankment. The earlier disappearance of snow deposited at the embankment slope increases the thawing period and the temperature gradient in the embankment compared with the natural ground. Infiltrated summer rainfall water lowered the near‐surface temperatures and subsequently warmed embankment fill materials down to 3.6‐m depth. Heat advection caused by the flow of subsurface water produced warming rates at depth in the embankment subgrade up to two orders of magnitude faster than by atmospheric warming (heat conduction). Subsurface water flow promoted permafrost thawing under the road embankment and led to an increase in active layer thickness. We conclude that the thermal stability of roadways along the Alaska Highway corridor is not maintainable in situations where water is flowing under the infrastructure unless mitigation techniques are used. Severe structural damages to the highway embankment are expected to occur in the next decade.

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“…This causes changes in ground stability (Rowland et al, 2010), hydrological conditions (Lawrence, Slater, & Swenson, 2012;Woo, 1986), ecology (Jorgenson, Racine, Walters, & Osterkamp, 2001), and coastal erosion (Lantuit & Pollard, 2008), all of which influence the daily life of local communities (Bartsch & Meyer, 2016). This has led to new transportation and infrastructure needs caused by changing ground and ice conditions (Larsen et al, 2008;Liljedahl et al, 2016), altering the way people are able to traverse the landscape (Doré, Niu, & Brooks, 2016). Natural hazards are generally thought to become more frequent (Nelson, Anisimov, & Shiklomanov, 2002).…”

Section: Introductionmentioning

confidence: 99%

Public Perception of Climate Change in Alaska: A Case Study of Opinion-Mining using Twitter

Bergstedt

Ristea

Resch

et al. 2018

giforum

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The Arctic, and with it the State of Alaska, USA, is an area highly impacted by climate change. Changing environmental conditions have started to impact local communities, causing a need for changes ranging from new infrastructure to the relocation of entire towns. These changes connected to rising temperatures have been shown to affect people's overall health, and their mental health in particular. Previous studies using opinion-mining and Twitter data have focused on large areas, not distinguishing between regions within countries. In the course of the research presented in this paper, we analysed Twitter data for the period 2013-2017, from which we extracted opinions concerning climate change topics by applying sentiment analysis (polarity and feelings) and climate change dictionaries, on a 10 x 10 km grid for the State of Alaska, USA. The number of climate change-relevant tweets was found to be much lower than reported in previous studies, where the USA was only considered in its entirety. After applying a topic-modelling approach, we found little difference between the spatial distributions of hotspots for the different climate change topics. A comparison with population data showed considerable biases towards English-speaking communities, tweets in indigenous languages being excluded when pre-defined dictionaries in English were used.

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Adaptation Methods for Transportation Infrastructure Built on Degrading Permafrost

Cited by 142 publications

References 39 publications

Status and Change of the Cryosphere in the Extended Hindu Kush Himalaya Region

Status and Change of the Cryosphere in the Extended Hindu Kush Himalaya Region

Impact of heat advection on the thermal regime of roads built on permafrost

Public Perception of Climate Change in Alaska: A Case Study of Opinion-Mining using Twitter

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