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Main Authors: Liu, Zirui, Ding, Tongtong, Kuang, Mingyue, Li, Zimeng, Zhao, Junyi, Zhang, A-Man, Li, Shuai
Format: Preprint
Published: 2026
Subjects:
Online Access:https://arxiv.org/abs/2602.22761
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author Liu, Zirui
Ding, Tongtong
Kuang, Mingyue
Li, Zimeng
Zhao, Junyi
Zhang, A-Man
Li, Shuai
author_facet Liu, Zirui
Ding, Tongtong
Kuang, Mingyue
Li, Zimeng
Zhao, Junyi
Zhang, A-Man
Li, Shuai
contents This study experimentally, numerically, and theoretically investigates the cavity/bubble dynamics and radiated acoustics during the water entry of a centimeter-scale cylindrical projectile with a conical nose. Experiments were conducted in a laboratory tank, employing synchronized high-speed imaging and hydrophone measurements to characterize the cavity closure modes and their resultant acoustic signatures across a range of Froude numbers. The acoustic signal features a weak radiated signal upon impact, followed by significant pressure oscillations spanning more than 20 cycles in the flow field after cavity elongation and pinch-off. A numerical model based on the Finite Volume Method (FVM) successfully captures these physical processes. Subsequently, a semi-theoretical model that incorporates the projectile's boundary effect is developed from potential flow theory. The model not only yields a dominant cavity oscillation frequency that agrees well with experimental data, but also reveals that the boundary effect leads to a cavity oscillation frequency markedly higher than the Minnaert frequency of an equivalent-volume ellipsoidal bubble containing an internal rigid core. The dominant cavity frequency falls nearly linearly with Fr, governed by nose geometry and projectile inertia. This study clarifies the underlying physics connecting cavity dynamics during water entry to underwater acoustic radiation.
format Preprint
id arxiv_https___arxiv_org_abs_2602_22761
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Acoustic Signatures of Pinch-Off Cavities During Water-Entry
Liu, Zirui
Ding, Tongtong
Kuang, Mingyue
Li, Zimeng
Zhao, Junyi
Zhang, A-Man
Li, Shuai
Fluid Dynamics
This study experimentally, numerically, and theoretically investigates the cavity/bubble dynamics and radiated acoustics during the water entry of a centimeter-scale cylindrical projectile with a conical nose. Experiments were conducted in a laboratory tank, employing synchronized high-speed imaging and hydrophone measurements to characterize the cavity closure modes and their resultant acoustic signatures across a range of Froude numbers. The acoustic signal features a weak radiated signal upon impact, followed by significant pressure oscillations spanning more than 20 cycles in the flow field after cavity elongation and pinch-off. A numerical model based on the Finite Volume Method (FVM) successfully captures these physical processes. Subsequently, a semi-theoretical model that incorporates the projectile's boundary effect is developed from potential flow theory. The model not only yields a dominant cavity oscillation frequency that agrees well with experimental data, but also reveals that the boundary effect leads to a cavity oscillation frequency markedly higher than the Minnaert frequency of an equivalent-volume ellipsoidal bubble containing an internal rigid core. The dominant cavity frequency falls nearly linearly with Fr, governed by nose geometry and projectile inertia. This study clarifies the underlying physics connecting cavity dynamics during water entry to underwater acoustic radiation.
title Acoustic Signatures of Pinch-Off Cavities During Water-Entry
topic Fluid Dynamics
url https://arxiv.org/abs/2602.22761