Litcius/Paper detail

Thermodynamic effects on nanobubble's collapse-induced erosion using molecular dynamic simulation

Marzieh Ghoohestani, Sasan Rezaee, Ebrahim Kadivar, Ould el Moctar

2023Physics of Fluids34 citationsDOIOpen Access PDF

Abstract

Using molecular dynamics simulation, we studied thermodynamic effects of a nanobubble's collapse-induced erosion occurring at different ambient temperatures. We analyzed the dynamics of a single nanobubble collapsing near an aluminum (Al) solid boundary immersed in water at temperatures ranging 10–60 °C (283–333 K). We used a momentum mirror protocol to investigate the nanobubble's collapse-induced shock wave as the associated nanojet formed and moved toward the solid boundary. The results showed that the nanojet was formed during the collapse process after the collision of the nanobubble with the shock wave. On the aluminum surface, the erosion at lower ambient temperatures was greater than at higher ambient temperatures.

Topics & Concepts

PhysicsMolecular dynamicsShock waveAluminiumErosionMechanicsMomentum (technical analysis)Impact craterShock (circulatory)CollisionBoundary value problemComposite materialMaterials scienceAstrobiologyGeomorphologyGeologyFinanceInternal medicineComputer scienceQuantum mechanicsComputer securityEconomicsMedicineMinerals Flotation and Separation TechniquesCalcium Carbonate Crystallization and InhibitionPickering emulsions and particle stabilization