The effectiveness of traditional vacuum preloading (TVP) for improving deep marine soft ground is fundamentally constrained by vacuum attenuation with depth and well resistance. To overcome these technical barriers, this study introduces a novel full-vacuum forced-drainage (FVFD) method, utilising an in situ vacuum generator positioned at the base of the drainage system. This design establishes an inverted vacuum profile that synergises with maximum hydrostatic pressure at depth, creating a superior hydraulic gradient for pore water expulsion. A rigorous analytical solution for consolidation was derived and verified against field monitoring data. A comparative case study demonstrated superior performance: the final settlement achieved by FVFD was 1.63 times that of TVP (0.65 m vs. 0.40 m), while the construction duration was reduced by over 60%. The findings reveal that FVFD effectively breaks the 10 m depth limitation of conventional surface-source systems, inducing significantly greater pore water pressure dissipation in deep layers. Although direct costs are 16.2% higher, the substantial reduction in project duration offers significant advantages in construction efficiency. This research establishes a highly efficient and proven strategy for deep soft ground improvement across diverse coastal and geotechnical infrastructure projects.
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Technical Paper|
May 29 2026
Full-vacuum forced-drainage for deep marine soft ground improvement Available to Purchase
L. Tang;
1School of Architectural Engineering,
Guangzhou Institute of Science and Technology
, Guangzhou, China
; School of Earth Sciences and Engineering, Sun Yat-sen University, Zhuhai, China; Southern Marine Science and Engineering Guangdong Laboratory Zhuhai, China; Guangdong Provincial Key Laboratory of Mineral Resources and Geological Processes, Guangzhou, ChinaCorresponding author L. Tang (eestls@mail.sysu.edu.cn)
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J. Huang;
J. Huang
2School of Earth Sciences and Engineering,
Sun Yat-sen University
, Zhuhai, China
; Southern Marine Science and Engineering Guangdong Laboratory Zhuhai, China; Guangdong Provincial Key Laboratory of Mineral Resources and Geological Processes, Guangzhou, China, E-mail: huangjn@mail2.sysu.edu.cn
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Q. Liu;
Q. Liu
3School of Earth Sciences and Engineering,
Sun Yat-sen University
, Zhuhai, China
; Southern Marine Science and Engineering Guangdong Laboratory Zhuhai, China; Guangdong Provincial Key Laboratory of Mineral Resources and Geological Processes, Guangzhou, China, E-mail: liuqx7@mail2.sysu.edu.cn
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Y. Wang;
Y. Wang
4School of Earth Sciences and Engineering,
Sun Yat-sen University
, Zhuhai, China
; Southern Marine Science and Engineering Guangdong Laboratory Zhuhai, China; Guangdong Provincial Key Laboratory of Mineral Resources and Geological Processes, Guangzhou, China, E-mail: 1046068345@qq.com
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X. Xiong
X. Xiong
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Corresponding author L. Tang (eestls@mail.sysu.edu.cn)
DISCLOSURE No authors of this manuscript have any competing financial or non-financial interests, currently or previously, including serving in an editorial capacity for the journal we are submitting to.
Publisher: Emerald Publishing
Received:
December 27 2025
Accepted:
March 27 2026
Online ISSN: 1751-7613
Print ISSN: 1072-6349
Funding
Funding Group:
- Award Group:
- Funder(s): National Natural Science Foundation of China
- Award Id(s): 42277142
- Funder(s):
- Award Group:
- Funder(s): National Cultivation Project for Guangzhou Institute of Science and Technology
- Award Id(s): 2024gjp002
- Funder(s):
- Award Group:
- Funder(s): Research Start-up Funding Project of Guangzhou Institute of Technology
- Award Id(s): 2023KYQ028
- Funder(s):
- Funding Statement(s): This study was supported by the National Natural Science Foundation of China (Grant numbers 42277142), the National Cultivation Project for Guangzhou Institute of Science and Technology (Grant numbers 2024gjp002), and the Research Start-up Funding Project of Guangzhou Institute of Technology (Grant numbers 2023KYQ028).
© 2026 Emerald Publishing Limited
2026
Emerald Publishing Limited
Licensed re-use rights only
Geosynthetics International 1–13.
Article history
Received:
December 27 2025
Accepted:
March 27 2026
Citation
Tang L, Huang J, Liu Q, Wang Y, Xiong X (2026;), "Full-vacuum forced-drainage for deep marine soft ground improvement". Geosynthetics International, Vol. ahead-of-print No. ahead-of-print. https://doi.org/10.1680/jgein.25.00233
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