Submitted:
26 January 2026
Posted:
27 January 2026
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Abstract

Keywords:
1. Introduction
2. Bubble Dynamics Within a Cluster using the Cell Model Approximation
3. Modified Model
4. Liquid Flow in the Inter-Bubble Space of a Cluster
5. Discussion
5.1. Dynamics of Bubble Growth and Collapse in a Cluster
5.2. Velocity and Pressure Fields in the Inter-Bubble Space
5.3. Heat and Mass Transfer Across the Interfacial Surface During Bubble Collapse
5. Conclusions
- – during bubble growth and compression, complex non-stationary microflows are formed inside the cluster due to the superposition of radial flows towards each bubble; these flows feature extremely high values of shear rates and shear stresses, the effect of which is present throughout the entire lifetime of the cluster;
- – calculations indicate that in the inter-bubble space, shear rates at local points on the boundaries of flow interaction can reach 106 s-1, which corresponds to a shear stress of approximately 1 kPа when water is the dispersed phase;
- – during collapse, each bubble in the cluster acts as the center of a spherical shock wave with a pressure amplitude that can reach 100 MPа.
Conflicts of Interest
Nomenclature
| pb | pressure in the vicinity of the bubble, Pa |
| R | bubble radius, m |
| Δ | distance between bubbles, m |
| r | radial coordinate, m |
| pf | external pressure, Pa |
| ρb | gas density inside the bubble, kg/m3 |
| uR | velocity of the bubble boundary motion, m/s |
| µ | dynamic viscosity, Pa s |
| σ | interfacial surface tension, N/m |
| γ(τ) | volumetric vapour content (void fraction) |
| Ψ | cell radius, m |
| θ | thickness of the thermal layer, m |
| pk | pressure at the cell boundary, Pa |
| pR | pressure at the bubble boundary, Pa |
| T | temperature, K |
| kb | number of bubbles |
| pm | average pressure, Pa |
| Q | latent heat of vaporization, J/kg |
| q | specific heat flux, W/m2 |
| c | specific heat capacity, J/(kg K) |
| modulus of the velocity vector. |
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