Effect of root water uptake on road movement across seasonal changes

Yuliana Yuliana; Arwan Apriyono; Anthony Kwan Leung; Suraparb Keawsawasvong; Viroon Kamchoom

doi:10.21741/9781644903414-77

Effect of root water uptake on road movement across seasonal changes

Yuliana Yuliana, Arwan Apriyono, Anthony Kwan Leung, Suraparb Keawsawasvong, Viroon Kamchoom^*

^*Corresponding author for this work

Department of Civil and Environmental Engineering

Research output: Chapter in Book/Conference Proceeding/Report › Conference Paper published in a book › peer-review

Abstract

The use of trees as roadside barriers provides benefits like noise and pollution control. On the other hand, the root systems can disrupt soil moisture, leading to uneven subsidence and impacting nearby structures. Knowing the appropriate distance between trees and pavement will allow for maximizing the plant's favourable impact on infrastructure. This study aimed to determine the safe distance between trees and pavement by examining the effects of transpiration on pore water pressure (PWP) and pavement subsidence under seasonal variations. The root water uptake was simplified in a finite element model using multiple hydraulic head boundaries and validated through field observations. A hypoplastic model was employed to simulate the non-linear behaviour and plastic strain accumulation in unsaturated soil. The findings indicate that the summer season exhibited a more noticeable change in negative PWP. Trees significantly reduce PWP, especially during summer seasons, creating higher suction near them due to evapotranspiration. Additionally, pavement edges closest to trees experience the most pronounced subsidence, likely due to a greater soil moisture deficit. Seasonal variations influence subsidence, with drier periods leading to more severe effects. Furthermore, the pavement with the distance 4 meters from the tree highlights a potential risk exceeded the cracking moment at 5^th summer period, indicating a high risk of damage.

Original language	English
Title of host publication	Civil and Environmental Engineering for Resilient, Smart and Sustainable Solutions
Editors	Tahar Ayadat
Publisher	Association of American Publishers
Pages	707-716
Number of pages	10
ISBN (Print)	9781644903414
DOIs	https://doi.org/10.21741/9781644903414-77
Publication status	Published - 2025
Event	1st International Conference on Civil and Environmental Engineering for Resilient, Smart and Sustainable Solutions, 2024 - Al Khobar, Saudi Arabia Duration: 3 Nov 2024 → 5 Nov 2024

Publication series

Name	Materials Research Proceedings
Volume	48
ISSN (Print)	2474-3941
ISSN (Electronic)	2474-395X

Conference

Conference	1st International Conference on Civil and Environmental Engineering for Resilient, Smart and Sustainable Solutions, 2024
Country/Territory	Saudi Arabia
City	Al Khobar
Period	3/11/24 → 5/11/24

Bibliographical note

Publisher Copyright:
© 2025, Association of American Publishers. All rights reserved.

Keywords

Hypoplastic Model
Pore Water Pressure
Root Water Uptake
Seasonal Condition
Settlement

Access to Document

10.21741/9781644903414-77

Cite this

Yuliana, Y., Apriyono, A., Leung, A. K., Keawsawasvong, S., & Kamchoom, V. (2025). Effect of root water uptake on road movement across seasonal changes. In T. Ayadat (Ed.), Civil and Environmental Engineering for Resilient, Smart and Sustainable Solutions (pp. 707-716). (Materials Research Proceedings; Vol. 48). Association of American Publishers. https://doi.org/10.21741/9781644903414-77

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title = "Effect of root water uptake on road movement across seasonal changes",

abstract = "The use of trees as roadside barriers provides benefits like noise and pollution control. On the other hand, the root systems can disrupt soil moisture, leading to uneven subsidence and impacting nearby structures. Knowing the appropriate distance between trees and pavement will allow for maximizing the plant's favourable impact on infrastructure. This study aimed to determine the safe distance between trees and pavement by examining the effects of transpiration on pore water pressure (PWP) and pavement subsidence under seasonal variations. The root water uptake was simplified in a finite element model using multiple hydraulic head boundaries and validated through field observations. A hypoplastic model was employed to simulate the non-linear behaviour and plastic strain accumulation in unsaturated soil. The findings indicate that the summer season exhibited a more noticeable change in negative PWP. Trees significantly reduce PWP, especially during summer seasons, creating higher suction near them due to evapotranspiration. Additionally, pavement edges closest to trees experience the most pronounced subsidence, likely due to a greater soil moisture deficit. Seasonal variations influence subsidence, with drier periods leading to more severe effects. Furthermore, the pavement with the distance 4 meters from the tree highlights a potential risk exceeded the cracking moment at 5th summer period, indicating a high risk of damage.",

keywords = "Hypoplastic Model, Pore Water Pressure, Root Water Uptake, Seasonal Condition, Settlement",

author = "Yuliana Yuliana and Arwan Apriyono and Leung, \{Anthony Kwan\} and Suraparb Keawsawasvong and Viroon Kamchoom",

note = "Publisher Copyright: {\textcopyright} 2025, Association of American Publishers. All rights reserved.; 1st International Conference on Civil and Environmental Engineering for Resilient, Smart and Sustainable Solutions, 2024 ; Conference date: 03-11-2024 Through 05-11-2024",

year = "2025",

doi = "10.21741/9781644903414-77",

language = "English",

isbn = "9781644903414",

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Yuliana, Y, Apriyono, A, Leung, AK, Keawsawasvong, S & Kamchoom, V 2025, Effect of root water uptake on road movement across seasonal changes. in T Ayadat (ed.), Civil and Environmental Engineering for Resilient, Smart and Sustainable Solutions. Materials Research Proceedings, vol. 48, Association of American Publishers, pp. 707-716, 1st International Conference on Civil and Environmental Engineering for Resilient, Smart and Sustainable Solutions, 2024, Al Khobar, Saudi Arabia, 3/11/24. https://doi.org/10.21741/9781644903414-77

Effect of root water uptake on road movement across seasonal changes. / Yuliana, Yuliana; Apriyono, Arwan; Leung, Anthony Kwan et al.
Civil and Environmental Engineering for Resilient, Smart and Sustainable Solutions. ed. / Tahar Ayadat. Association of American Publishers, 2025. p. 707-716 (Materials Research Proceedings; Vol. 48).

Research output: Chapter in Book/Conference Proceeding/Report › Conference Paper published in a book › peer-review

TY - GEN

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AU - Apriyono, Arwan

AU - Leung, Anthony Kwan

AU - Keawsawasvong, Suraparb

AU - Kamchoom, Viroon

PY - 2025

Y1 - 2025

N2 - The use of trees as roadside barriers provides benefits like noise and pollution control. On the other hand, the root systems can disrupt soil moisture, leading to uneven subsidence and impacting nearby structures. Knowing the appropriate distance between trees and pavement will allow for maximizing the plant's favourable impact on infrastructure. This study aimed to determine the safe distance between trees and pavement by examining the effects of transpiration on pore water pressure (PWP) and pavement subsidence under seasonal variations. The root water uptake was simplified in a finite element model using multiple hydraulic head boundaries and validated through field observations. A hypoplastic model was employed to simulate the non-linear behaviour and plastic strain accumulation in unsaturated soil. The findings indicate that the summer season exhibited a more noticeable change in negative PWP. Trees significantly reduce PWP, especially during summer seasons, creating higher suction near them due to evapotranspiration. Additionally, pavement edges closest to trees experience the most pronounced subsidence, likely due to a greater soil moisture deficit. Seasonal variations influence subsidence, with drier periods leading to more severe effects. Furthermore, the pavement with the distance 4 meters from the tree highlights a potential risk exceeded the cracking moment at 5th summer period, indicating a high risk of damage.

AB - The use of trees as roadside barriers provides benefits like noise and pollution control. On the other hand, the root systems can disrupt soil moisture, leading to uneven subsidence and impacting nearby structures. Knowing the appropriate distance between trees and pavement will allow for maximizing the plant's favourable impact on infrastructure. This study aimed to determine the safe distance between trees and pavement by examining the effects of transpiration on pore water pressure (PWP) and pavement subsidence under seasonal variations. The root water uptake was simplified in a finite element model using multiple hydraulic head boundaries and validated through field observations. A hypoplastic model was employed to simulate the non-linear behaviour and plastic strain accumulation in unsaturated soil. The findings indicate that the summer season exhibited a more noticeable change in negative PWP. Trees significantly reduce PWP, especially during summer seasons, creating higher suction near them due to evapotranspiration. Additionally, pavement edges closest to trees experience the most pronounced subsidence, likely due to a greater soil moisture deficit. Seasonal variations influence subsidence, with drier periods leading to more severe effects. Furthermore, the pavement with the distance 4 meters from the tree highlights a potential risk exceeded the cracking moment at 5th summer period, indicating a high risk of damage.

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EP - 716

BT - Civil and Environmental Engineering for Resilient, Smart and Sustainable Solutions

A2 - Ayadat, Tahar

PB - Association of American Publishers

T2 - 1st International Conference on Civil and Environmental Engineering for Resilient, Smart and Sustainable Solutions, 2024

Y2 - 3 November 2024 through 5 November 2024

ER -

Effect of root water uptake on road movement across seasonal changes

Abstract

Publication series

Conference

Bibliographical note

Keywords

Access to Document

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