[1. Brennen C.E., Cavitation in medicine. Interface Focus, 5 (2015).10.1098/rsfs.2015.0022454984726442145]Search in Google Scholar
[2. Gogate P.R., Kabadi A.M., A review of applications of cavitation in biochemical engineering/biotechnology. Biochemical Engineering Journal, 44 (2009), 60-72.]Search in Google Scholar
[3. Szkodo M., Estimation of cavitation erosion resistance of materials. Advances in Materials Science, 6 (2006), 43-48.]Search in Google Scholar
[4. Rosenberg LD. Powerful ultrasonic fields, Nauka Moscow (1968), 18-45.]Search in Google Scholar
[5. Peng C-h, Liu Z-y, Wei X-z. Failure analysis of a steel tube joint perforated by corrosion in a well-drilling pipe. Engineering Failure Analysis, 25 (2012), 13-28.]Search in Google Scholar
[6. Smith L. Control of corrosion in oil and gas production tubing. British Corrosion Journal, 34, 4 (1999), 247-53.]Search in Google Scholar
[7. Institute AP. API 5-CT specification for casing and tubing, 9th edition, 2011.]Search in Google Scholar
[8. Hernandez S., Linares F.L., Bruzual J., Luzon J.G., Isolation of Potential Corrosion Inhibiting Compounds in Crude Oils. NACE International.]Search in Google Scholar
[9. Brennen C.E., Cavitation and Bubble Dynamics: Oxford University Press; 1995.]Search in Google Scholar
[10. Brondel D, Edwars R, Hayman A, Hill D, Mehta S, Semerad T., Corrosion in the Oil industry. Oilfield Review, 6 (1994).]Search in Google Scholar
[11. ASTM. G32-10 Standard Test Method for Cavitation Erosion Using Vibratory Apparatus, 2010.]Search in Google Scholar
[12. Ultrasonics H., UP200s/UP400S Instruction manual Ultrasonic processors for Laboratories.]Search in Google Scholar
[13. Dugan G., The Versatile PAC Polymer. National Driller, 30(1) (2009), 60-72.]Search in Google Scholar
[14. El-Lateef H.M., Abbasov V.M., Aliyeva L.I., Ismayilov T.A., Some surfactants based on the vegetable oils as CO2 corrosion Inhibitors for mild steel in oilfield formation water. International Journal of Corrosion Scale Inhibition, 4(2) (2015), 162-175.10.17675/2305-6894-2015-4-2-162-175]Search in Google Scholar
[15. Brujan E.A., Cavitation bubble dynamics in non-Newtonian fluids. Polymer Engineering & Science, 49(3) (2009), 419-431.10.1002/pen.21292]Search in Google Scholar
[16. Gruzdkov A. A, Petrov Y.V., Cavitation breakup of low-and high-viscosity liquids. Technical Physics, 53(3) (2008), 291-295.10.1134/S106378420803002X]Search in Google Scholar
[17. Arora M., Cavitation Inception on Microparticles: A Self-Propelled Particle Accelerator. Physical Review Letters, 92(17) (2004), 174501.10.1103/PhysRevLett.92.17450115169155]Search in Google Scholar
[18. Gronroos A, Pentti P, Hanna K., Ultrasonic degradation of aqueous carboxymethylcellulose: effect of viscosity, molecular mass, and concentration. Ultrasonic Sonochemistry, 15 (2008), 644-652.10.1016/j.ultsonch.2007.09.00517986397]Search in Google Scholar
[19. Mettin R., et al., Imaging of the influence of surfactants on bubble structures. DAGA. Stuttgart 2007, 119-20.]Search in Google Scholar
[20. Lee J, Kentish S, Matula T.J., Ashokkumar M., Effect of surfactants on inertial cavitation activity in a pulsed acoustic field. The Journal of Physical Chemistry B, 109 (2005), 16860-16865.]Search in Google Scholar
