Abstract
We have studied the molecular level cavitation mechanisms and bubble growth kinetics in soft gelatin hydrogel and water. The apparent difference in cavitation threshold pressure between that generates in pure water and that in gelatin hydrogel is considered. Gelatin, which is derived from collagen, is frequently used as a brain simulant material. In liquid, cavitation bubble is created when surrounding pressure drops below the saturation vapor pressure. In principle, a cavitation bubble should continue to grow as long as tensile pressure continues to increase in the system. In our study, using molecular dynamics simulation, we have investigated the pressure requirement for a nanoscale cavitation to grow in water and gel. First, we have modeled a gel like structure with a preexisting bubble of 5 nm radius. A control model containing a 5 nm bubble in pure water is also created. Then, we have applied hydrostatic tensile pressure at two different expansion rates in the gel and water models. The results show that a gel-like structure requires higher pressure for the cavitation to grow, and both gel and water models exhibit strain rate effect on the cavitation threshold pressure. We have also found that the cavitation collapse time is dominated by the viscosity of the medium.
Highlights
We have studied the molecular level cavitation mechanisms and bubble growth kinetics in soft gelatin hydrogel and water
Understanding the cavitation mechanisms in soft materials gained attention due to its potential implication in biomedical related applications[2,3,4,5]. Soft materials such as gelatin hydrogels are widely used as a brain simulant material[6,7,8]
We have studied the heterogenous cavitation bubble growth mechanisms in a gel-like and pure water system
Summary
We have studied the molecular level cavitation mechanisms and bubble growth kinetics in soft gelatin hydrogel and water. Understanding the cavitation mechanisms in soft materials gained attention due to its potential implication in biomedical related applications[2,3,4,5] Soft materials such as gelatin hydrogels are widely used as a brain simulant material[6,7,8]. Surface tension and viscosity of gelatin gel are not constant, rather, they depend on gelation time and concentration[16] Due to these structural and chemical instabilities and time variant material properties, accurately predicting cavitation pressure for gel be very challenging. It has been hypothesized that the rise in cavitation threshold in gel is Mechanical and Aerospace Engineering, University of Texas at Arlington, Arlington, Texas, USA. ✉e-mail: aadnan@ uta.edu www.nature.com/scientificreports/
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