3D localization of hydrating sources in concrete based on ae and tomography

Korda, Eleni; Chen, Fuzhen; Chai, Hwa Kian; De Schutter, Geert; Aggelis, Dimitrios G.

3D localization of hydrating sources in concrete based on ae and tomography

Eleni Korda (UGent) , Fuzhen Chen, Hwa Kian Chai, Geert De Schutter (UGent) and Dimitrios G. Aggelis

(2026) SENSORS. 26(4).

Author

Eleni Korda (UGent) , Fuzhen Chen, Hwa Kian Chai, Geert De Schutter (UGent) and Dimitrios G. Aggelis

Organization

Department of Structural Engineering and Building Materials

Project

Active control of concrete curing by acoustic emission (ACCCAE)

Abstract

Plastic shrinkage and self-desiccation, along with the associated early-age cracking, are still among the most important factors that influence long-term performance of concrete structures, including durability. Superabsorbent polymers (SAPs) have been widely researched for application in concrete to mitigate shrinkage through facilitating effective internal curing by releasing water into the mixture to promote continuous hydration of cement. The acoustic emission (AE) monitoring technique, due to its high sensitivity, has proven very effective in tracking the process of water release by SAPs in concrete during early-stage curing. Typically, AE parameters such as cumulative activity, amplitude and energy are utilized to characterize the kinetics of curing processes. While these parameters indicate well the internal activity of SAPs in time, they do not offer information on the precise location of the active sources within the material's volume, leaving a crucial gap in the understanding of the ongoing microstructural changes caused by internal water distribution and cement hydration. In this sense, AE event source localization can offer information about the active zones of water hydration activity in the material 3D domain, allowing detection of their evolution during concrete curing. Meanwhile, Acoustic Emission Tomography (AET) computes ultrasonic velocity distributions in different periods of monitoring, which are governed by acoustic characteristics of the concrete mixtures, to visualize material stiffness development spatially and temporally. This level of insight is particularly important for SAP concrete, where uniformity of internal water curing is essential for ensuring long-term durability and material soundness. By visualizing how the hydration sources evolve in real time, these methods offer an effective, non-destructive, and cost-effective solution for early-age concrete quality control, which would be challenging to achieve through other techniques.

Keywords

acoustic emission, 3D localization, travel-time tomography, superabsorbent polymers, hydration, RECONSTRUCTION TECHNIQUE, CLASSIFICATION, BEHAVIOR

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Citation

Please use this url to cite or link to this publication: http://hdl.handle.net/1854/LU-01KKXNPCH8SGRGJ0KCE00JT50J

MLA: Korda, Eleni, et al. “3D Localization of Hydrating Sources in Concrete Based on Ae and Tomography.” SENSORS, vol. 26, no. 4, 2026, doi:10.3390/s26041345.
APA: Korda, E., Chen, F., Chai, H. K., De Schutter, G., & Aggelis, D. G. (2026). 3D localization of hydrating sources in concrete based on ae and tomography. SENSORS, 26(4). https://doi.org/10.3390/s26041345
Chicago author-date: Korda, Eleni, Fuzhen Chen, Hwa Kian Chai, Geert De Schutter, and Dimitrios G. Aggelis. 2026. “3D Localization of Hydrating Sources in Concrete Based on Ae and Tomography.” SENSORS 26 (4). https://doi.org/10.3390/s26041345.
Chicago author-date (all authors): Korda, Eleni, Fuzhen Chen, Hwa Kian Chai, Geert De Schutter, and Dimitrios G. Aggelis. 2026. “3D Localization of Hydrating Sources in Concrete Based on Ae and Tomography.” SENSORS 26 (4). doi:10.3390/s26041345.
Vancouver: 1.
Korda E, Chen F, Chai HK, De Schutter G, Aggelis DG. 3D localization of hydrating sources in concrete based on ae and tomography. SENSORS. 2026;26(4).
IEEE: [1]
E. Korda, F. Chen, H. K. Chai, G. De Schutter, and D. G. Aggelis, “3D localization of hydrating sources in concrete based on ae and tomography,” SENSORS, vol. 26, no. 4, 2026.

@article{01KKXNPCH8SGRGJ0KCE00JT50J,
  abstract     = {{Plastic shrinkage and self-desiccation, along with the associated early-age cracking, are still among the most important factors that influence long-term performance of concrete structures, including durability. Superabsorbent polymers (SAPs) have been widely researched for application in concrete to mitigate shrinkage through facilitating effective internal curing by releasing water into the mixture to promote continuous hydration of cement. The acoustic emission (AE) monitoring technique, due to its high sensitivity, has proven very effective in tracking the process of water release by SAPs in concrete during early-stage curing. Typically, AE parameters such as cumulative activity, amplitude and energy are utilized to characterize the kinetics of curing processes. While these parameters indicate well the internal activity of SAPs in time, they do not offer information on the precise location of the active sources within the material's volume, leaving a crucial gap in the understanding of the ongoing microstructural changes caused by internal water distribution and cement hydration. In this sense, AE event source localization can offer information about the active zones of water hydration activity in the material 3D domain, allowing detection of their evolution during concrete curing. Meanwhile, Acoustic Emission Tomography (AET) computes ultrasonic velocity distributions in different periods of monitoring, which are governed by acoustic characteristics of the concrete mixtures, to visualize material stiffness development spatially and temporally. This level of insight is particularly important for SAP concrete, where uniformity of internal water curing is essential for ensuring long-term durability and material soundness. By visualizing how the hydration sources evolve in real time, these methods offer an effective, non-destructive, and cost-effective solution for early-age concrete quality control, which would be challenging to achieve through other techniques.}},
  articleno    = {{1345}},
  author       = {{Korda, Eleni and Chen, Fuzhen and Chai, Hwa Kian and De Schutter, Geert and Aggelis, Dimitrios G.}},
  issn         = {{1424-8220}},
  journal      = {{SENSORS}},
  keywords     = {{acoustic emission,3D localization,travel-time tomography,superabsorbent polymers,hydration,RECONSTRUCTION TECHNIQUE,CLASSIFICATION,BEHAVIOR}},
  language     = {{eng}},
  number       = {{4}},
  pages        = {{20}},
  title        = {{3D localization of hydrating sources in concrete based on ae and tomography}},
  url          = {{http://doi.org/10.3390/s26041345}},
  volume       = {{26}},
  year         = {{2026}},
}

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3D localization of hydrating sources in concrete based on ae and tomography

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