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Thermal Behavior of Road Embankments and impact of Snow in Ditches
Luleå University of Technology, Department of Civil, Environmental and Natural Resources Engineering, Mining and Geotechnical Engineering.ORCID iD: 0009-0006-5705-5485
2025 (English)Doctoral thesis, comprehensive summary (Other academic)
Abstract [en]

In cold climate regions, seasonal snow accumulation in road ditches plays a critical role in governing the thermal behavior of road embankments. Snow exerts a spatially uneven thermal influence on heat transfer within the embankment due to its strong insulating properties, which can lead to differential frost heave and the formation of cracks on the road surface. However, accurately quantifying this insulation effect requires detailed knowledge of the thermal regime of the snow cover accumulated in the ditches, including its temporal evolution throughout the winter season.

Snow is a porous medium characterized by a high volume fraction of air, which significantly reduces the thermal conductivity of snow and provides a strong insulating capacity. This insulation creates a natural temperature gradient between the snow surface and its base, governing the rate of heat transfer through the snow. Once snow is deposited, a temperature gradient develops, initiating metamorphic processes that alter the morphology and bonding of the snow grains. These microstructural changes lead to temporal variations in the thermal conductivity of snow, making its accurate determination over time particularly challenging. Furthermore, freezing-melting cycles modify the content of unfrozen liquid water within the snow structure, which not only complicates the quantification of latent heat exchanges but also exerts a significant influence on the effective thermal conductivity.

To address these challenges and gain a deeper understanding of the thermal dynamics in snow-covered road embankments, two experimental field sites were established in Luleå, Sweden. The first site, located on the premises of the Luleå University of Technology, was designed to investigate the thermal regime of a natural undisturbed snow cover and its impact on temperatures at the soil–snow interface, as well as within the shallow subsurface soil layer. The second site was located in a road ditch near Luleå Airport, where the snow cover consisted of a mixture of naturally accumulated snow and plowed snow from the adjacent road. The purpose of this site was to investigate the thermal regime of the snow cover in the ditch and its influence on the thermal conditions of the road embankment. The objective was to investigate the thermal regime of both the snow cover in the ditch and the road embankment influenced by snow accumulation during the winter season.

At both sites, the thermal regime of the accumulated snow was continuously monitored by measuring the snow temperature at different heights throughout the winter season. Meteorological conditions were also recorded using a weather station installed at each site. At the site with natural snow accumulation, the thermal influence of snow cover on subsurface soil was measured down to a depth of 40 cm. In contrast, at the experimental site in the road ditch, the thermal regime of the entire road embankment was investigated. To provide a comprehensive overview, the temperature distribution was measured from the road surface to a depth of 2 m, as well as from the surface of the ditch to the same depth.

Analysis of the thermal regimes of snow cover at each experimental site reveals that the natural undisturbed snow cover possesses a greater insulating capacity compared to snow cover accumulated in ditches, due to differences in metamorphic processes. The metamorphism of each type of snow cover is influenced by factors such as history of deposition and environmental conditions.

To assess the insulating behavior of the snow in the ditch, the thermal conductivity of the snow cover at different heights was evaluated over time. Since manual measurements are restricted to discrete points, estimation of the thermal conductivity of snow over a period enables the consideration of continuous changes in the properties of snow driven by metamorphism. To achieve a realistic estimate, a mathematical approach was applied to analyze heat transfer processes within the snow cover based on field measurements. For depths where melting occurred, a novel method was developed to estimate the unfrozen water content of the snow, a parameter that is otherwise very difficult to measure or determine. Based on the analysis, an empirical relation was proposed to estimate the thermal conductivity of snow in the ditch, which is practically useful under similar climatic conditions. However, it was not possible to derive an empirical formula for the unfrozen water content, since the snow undergoes different metamorphic processes at different depths, resulting in highly variable behavior.

Furthermore, the thermal regime of the road embankment during the winter season was assessed using a one-dimensional finite-difference model validated against field measurements. In this model, a new approach was introduced to account for cloud cover in calculating incoming long-wave radiation, which plays a key role in the energy balance of the road surface and strongly affects the surface temperature. The influence of traffic was also incorporated by deriving a representative daily traffic load based on measurements collected over a two-week period. In general, the model improved the estimation of the road surface temperature and provided a more accurate assessment of the thermal regime of the road embankment.

The findings of this study improve the understanding of the thermal regime of road embankments in typical cold-climate regions with significant snow precipitation. Incorporating the thermal behavior of snow in design and maintenance strategies offers critical guidance for implementing measures that mitigate freezing-induced damage and improve the long-term durability of embankments. Furthermore, understanding the thermal influence of snow cover in road ditches can support the development of targeted snow management strategies to optimize its insulating effect. Such strategies may include the complete or partial removal of snow from the ditch or densification of the snowpack to modify its thermal impact on the road embankment. These measures can help improve the long-term performance of the embankment.
Place, publisher, year, edition, pages
Luleå: Luleå University of Technology, 2025.
Series
Doctoral thesis / Luleå University of Technology 1 jan 1997 → …, ISSN 1402-1544
National Category
Geotechnical Engineering and Engineering Geology
Research subject
Soil Mechanics
Identifiers
URN: urn:nbn:se:ltu:diva-115180ISBN: 978-91-8048-931-7 (print)ISBN: 978-91-8048-932-4 (electronic)OAI: oai:DiVA.org:ltu-115180DiVA, id: diva2:2007521
Public defence
2025-12-04, E632, Luleå University of Technology, Luleå, 10:00 (English)
Opponent
Supervisors
Available from: 2025-10-20 Created: 2025-10-20 Last updated: 2025-11-14Bibliographically approved
List of papers
1. Field measurements at a road embankment during a winter season in northern Sweden
Open this publication in new window or tab >>Field measurements at a road embankment during a winter season in northern Sweden
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2025 (English)In: Transportation Geotechnics, E-ISSN 2214-3912, Vol. 52, article id 101553Article in journal (Refereed) Published
Abstract [en]

Understanding the thermal regime of road embankments in cold climates during winter is essential for efficient road design and accurate estimation of maintenance frequencies to reduce freeze-induced damage. In response to the challenging climate conditions in northern Sweden, an experimental field setup was designed to assess the thermal impact of culverts and accumulated snow in ditches on the thermal regime of road embankments during a winter season. This study provides detailed information on the experimental setup, highlights potential challenges from installation phase to data acquisition, and addresses measurement errors. Methods to ensure accuracy and obtain reliable data are also presented. Additionally, some of the obtained measurement results are included in this paper. The results show that snow impacts the thermal regime of the embankment from the onset of accumulation in the ditch, when the snow cover is still thin, until it reaches a depth of 65 cm. Beyond this depth, the soil beneath the snow remains almost unfrozen throughout the winter season. Additionally, the temperature distribution measurements within the embankment indicate that freezing progresses faster near the culvert compared to the rest of the embankment. However, once the culvert ends are insulated by snow cover, the frost depth in the soil near the culvert does not increase significantly, while the rest of the road continues to freeze gradually to greater depths throughout the winter season. The measurement results presented in this study provide researchers with a reliable dataset for validating numerical models in related research areas simulating cold-climate conditions. Additionally, these results enhance the understanding of the thermal regime of road embankments in typical cold climates and offer valuable insights for planning road maintenance and construction in such regions. Furthermore, this study provides essential information for researchers aiming to design and optimize experimental measurement setups in similar investigations.
Place, publisher, year, edition, pages
Elsevier Ltd, 2025
Keywords
Road embankment, Thermal regime, Cold climate Culvert, Snow cover
National Category
Geotechnical Engineering and Engineering Geology
Research subject
Soil Mechanics
Identifiers
urn:nbn:se:ltu:diva-112363 (URN)10.1016/j.trgeo.2025.101553 (DOI)001468591300001 ()2-s2.0-105001555002 (Scopus ID)
Funder
Swedish Transport Administration
Note

Validerad;2025;Nivå 2;2025-04-14 (u5);

Full text license: CC BY 4.0;

Available from: 2025-04-14 Created: 2025-04-14 Last updated: 2025-10-21Bibliographically approved
2. Influence of different seasonal snow cover on thermal regime of the ground
Open this publication in new window or tab >>Influence of different seasonal snow cover on thermal regime of the ground
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2024 (English)In: Geotechnical Engineering Challenges to Meet Current and Emerging Needs of Society: Proceedings of the XVIII European Conference on Soil Mechanics and Geotechnical Engineering / [ed] Nuno Guerra; Manuel Matos Fernandes; Cristiana Ferreira; António Gomes Correia; Alexandre Pinto; Pedro Sêco Pinto, CRC Press, 2024, p. 3165-3170Conference paper, Published paper (Refereed)
Abstract [en]

Ground thermal regime in cold regions is influenced by seasonal snow cover, which acts as an insulating layer influencing the heat transfer between the atmosphere and the underlying soil. The thermal properties of the snow change with different environmental conditions, playing a crucial role to determine the thermal state of the sub-surface soil. Previous research in this field have faced challenges to accurately characterize thermal properties of seasonal snowpacks under varying spatial and meteorological conditions. To address this issue, two experimental field setups were constructed in Luleå, Sweden, to observe the temperature distribution of the snowpack and the ground sub-surface soil. The first experiment studied a naturally accumulated, undisturbed snowpack. The second experiment was conducted on a roadside ditch where the snowpack consists of a combination of natural accumulated snow and plowed snow from the adjacent road. In this research, heat transfer processes at both field sites were monitored over a winter season each to better understand the complex relationship between snow cover properties and sub-surface thermal regime. Furthermore, thermal conductivity of a basal layer in each snowpack was calculated over a time period, based on the field measurements. The results showed that the history of snow deposition, meteorological conditions, and changes in soil moisture impact the metamorphism process within the snowpack, thereby altering the structure of the layers of snowpack and its influence on the thermal regime of the sub-surface soil. The findings of this research have important applications in various sectors, from mining to road maintenance and agriculture.
Place, publisher, year, edition, pages
CRC Press, 2024
Keywords
thermal regime, seasonal snow, thermal conductivity, heat transfer
National Category
Civil Engineering Soil Science
Research subject
Soil Mechanics; Experimental Mechanics
Identifiers
urn:nbn:se:ltu:diva-115178 (URN)10.1201/9781003431749-622 (DOI)
Conference
European Conference on Soil Mechanics and Geotechnical Engineering (ECSMGE 24), Lisbon, Portugal, 26–30 August 2024
Note

ISBN for host publication: 978-1-032-54816-6;

Fulltext license: CC BY-NC-ND

Available from: 2025-10-20 Created: 2025-10-20 Last updated: 2025-10-21Bibliographically approved
3. Evaluating the thermal regime and unfrozen water content of snow accumulated in road ditches: a case study from northern Sweden
Open this publication in new window or tab >>Evaluating the thermal regime and unfrozen water content of snow accumulated in road ditches: a case study from northern Sweden
(English)Manuscript (preprint) (Other academic)
National Category
Other Civil Engineering
Research subject
Soil Mechanics
Identifiers
urn:nbn:se:ltu:diva-115179 (URN)
Available from: 2025-10-20 Created: 2025-10-20 Last updated: 2025-10-21Bibliographically approved
4. A dynamic boundary condition finite difference model for predicting pavement profile temperatures: Development and validation
Open this publication in new window or tab >>A dynamic boundary condition finite difference model for predicting pavement profile temperatures: Development and validation
Show others...
2024 (English)In: Transportation Engineering, E-ISSN 2666-691X, article id 100287Article in journal (Refereed) Published
Abstract [en]

The appearance of ground frost is of vital importance in construction and maintenance of roads in cold climates. Frost often causes ground heave and subsequent road damage, which must be taken into account in designing the road structure. Frost depth, pavement temperature, and freezing/thawing cycles are also important for estimating the frequency of road maintenance and treatment. Various analytical, numerical, and empirical models have been developed to estimate the surface temperature of the pavement and to model the heat flow in the underlying layers. The pavement surface experiences a variety of intricate nonlinear heat transfer mechanisms during winter, making it challenging to accurately model the surface boundary. Dynamic variation of parameters such as cloud cover and traffic density during the modeling period introduces additional complexity. To address this challenge, we have established an experimental setup in Luleå, Sweden, to measure pavement profile temperatures during the winter season. Additionally, we have developed a Finite Difference Model that utilizes local weather data including dynamic cloud cover, and which also takes traffic into account. The experimental and simulation findings demonstrate how the impact of surface temperature fluctuations diminishes and, more or less, vanishes for depths more than 55 [cm] below the pavement surface. The Finite Difference Model presented in this study exhibits the ability to forecast the pavement profile temperatures, including the surface temperature based on weather conditions, with acceptable precision for at least 3 days. As a consequence, a reasonable assessment of pavement layer conditions appears feasible based on local weather conditions, and the model can serve as a useful tool for planning road maintenance and construction in cold regions.
Place, publisher, year, edition, pages
Elsevier, 2024
Keywords
Pavement profile temperatures, Surface boundary condition, Cloud factor, Traffic induced heat flux
National Category
Geotechnical Engineering and Engineering Geology Infrastructure Engineering
Research subject
Soil Mechanics; Experimental Mechanics
Identifiers
urn:nbn:se:ltu:diva-110695 (URN)10.1016/j.treng.2024.100287 (DOI)2-s2.0-85210027346 (Scopus ID)
Funder
Swedish Transport Administration
Note

Validerad;2024;Nivå 1;2024-11-27 (signyg);

Full text license: CC BY-NC-ND

Available from: 2024-11-12 Created: 2024-11-12 Last updated: 2025-10-21Bibliographically approved

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5678910118 of 21
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