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Research Article| April 07 2026

Development of a centrifuge device to model submarine gravity flow and seabed response Available to Purchase

X. Chen;
X. Chen
*Institute of Hypergravity Science and Technology,
Zhejiang University
, Hangzhou,
China
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J. Tan;
J. Tan
Institute of Hypergravity Science and Technology,
Zhejiang University
, Hangzhou,
China
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S. Ren;
S. Ren
Institute of Hypergravity Science and Technology,
Zhejiang University
, Hangzhou,
China
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B. Zhu;
B. Zhu
§Institute of Hypergravity Science and Technology,
Zhejiang University
, Hangzhou,
China
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D. Kong
ORCID logo 0000-0002-9122-9294
D. Kong
Institute of Hypergravity Science and Technology,
Zhejiang University
, Hangzhou,
China
Corresponding author D. Kong (deqiong_kong@zju.edu.cn)
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Author & Article Information
Corresponding author D. Kong (deqiong_kong@zju.edu.cn)

COMPETING INTERESTS The authors declare no competing interests.

Publisher: Emerald Publishing
Received: August 29 2025
Accepted: February 28 2026
Funding
Funding Group:
  • Award Group:
    • Funder(s):
       Natural Science Foundation of Zhejiang Province
    • Award Id(s):
      LR23E090001
  • Award Group:
    • Funder(s):
       National Natural Science Foundation of China
    • Award Id(s):
      52571309
      ,
      52588202
  • Award Group:
    • Funder(s):
       Fundamental Research Funds for the Central Universities
    • Award Id(s):
      2024FZZX03-03-02
  • Funding Statement(s):
     The authors acknowledge the financial support from the Natural Science Foundation of Zhejiang Province (Grant no. LR23E090001), the National Natural Science Foundation of China (Grant nos. 52571309; 52588202), the Fundamental Research Funds for the Central Universities (2024FZZX03-03-02), and the assistance provided by Mr. Zhenli Li, Mr. Zizhuang Yan, and Mr. Shuai Hong on the centrifuge test.
© 2026 Emerald Publishing Limited
2026
Emerald Publishing Limited
Licensed re-use rights only
Geotechnique Letters 1–7.
https://doi.org/10.1680/jgele.25.00093
Article history
Received:
August 29 2025
Accepted:
February 28 2026

This paper introduces a state-of-the-art centrifuge device designed to simulate submarine gravity flows and their effects on the seabed. It features a double-gate release system, enabling the rapid discharge of gravity flow slurry. Using this device, the responses of pore pressure and soil pressure in the seabed were experimentally investigated for the first time. Results demonstrate that critical flow parameters, such as the front velocity and Froude number, align well with field data. Unlike subaerial debris flows, seabed deformation occurs primarily behind the flow head, rather than upon its arrival, due to the entrapment of a thin water film. Future advancements, including scaling up the device and integrating advanced monitoring technologies, are underway.

Keywords:
centrifuge modelling, landslides, excess pore pressure, gravity flow, sands
© 2026 Emerald Publishing Limited
2026
Emerald Publishing Limited
Licensed re-use rights only
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