[1. Allouch A., Bourmine K., Monmayrant A., Gauthier-Lafaye o., Geoffroy S., Guo A.-M., Joseph P. (2014), Microbubbles for optofluidics: controlled defects in bubble crystals, Microfluidics and Nanofluidics, 549-560.10.1007/s10404-014-1339-5]Search in Google Scholar
[2. Al-Mashhadani M.K.H., Wilkinson S.J., Zimmerman W.B. (2015), Airlift bioreactor for biological applications with microbubble mediated transport processes, Chemical Engineering Science, Vol. 137, 243-253.]Search in Google Scholar
[3. Al-Mashhadani M.K.H., Bandulasena H.C.H., Zimmerman W.B. (2012), CO2 mass transfer induced through an airlift loop by a microbubble cloud generated by fluidic oscillation, Industrial and Engineering Chemistry Research, Vol. 51, 1864-1877.]Search in Google Scholar
[4. Bogdevich V.G., Evseev A.R,., Mljuga A.G., Migirenko G. S. (1978), Gas saturation effect on near-wall turbulence characteristics, Proc of 2nd International Conference on Drag Reduction, Cambridge, BHRA, 25-34.]Search in Google Scholar
[5. Coward T., Lee J. G. M., Caldwell G.S. (2015), The effect of bubble size on the efficiency and economics of harvesting microalgae by foam flotation, Journal of Applied Phycology, Vol. 27, 733-742.]Search in Google Scholar
[6. Demirbas A., Demirbas M.F. (2011) Importance of algae oil as a source of biodiesel, Energy Conversion and Management, Vol. 52, 163-170.]Search in Google Scholar
[7. Hanotu J., Bandulasena H.C.H., Zimmerman W.B. (2012), Microflotation performance for algal separation, Biotechnology and Bioengineering, Vol. 109, 1663-1673.]Search in Google Scholar
[8. Hanotu J., Bandulasena H.C.H., Chiu T. Y., Zimmerman W.B. t(2013), Oil emulsion separation with fluidic oscillator generated microbubbles, International Journal of Multiphase Flow, Vol. 56, 119-l125.]Search in Google Scholar
[9. Hashimoto M., Mayers B., Garstecki P., Whitesides G. M. (2006), Flowing lattices of bubbles as tunable, self-assembled diffracting gratings, Small, Vol. 2, 1292-1298]Search in Google Scholar
[10. Hu X., Liu B., Zhou J., Jin R. Qiao S., Liu G. (2015), CO2 fixation, lipid production, and power generation by a novel air-lift-type microbial carbon capture cell system, Environmental Science and Technology, Vol. 49, 10710-10717.]Search in Google Scholar
[11. James A., Vukasinovic B., Smith M. K., Glezer A, (2003), Vibration-induced drop atomization and bursting, Journal of Fluid Mechanics, Vol. 476, 1-28.]Search in Google Scholar
[12. Jones S.M.J., Harrison S.T.L. (2014), Aeration energy requirements for lipid production by Scenedesmus sp. in airlift bioreactors, Algal Research, Vol. 5, 249-257.10.1016/j.algal.2014.03.003]Search in Google Scholar
[13. Kanagawa T. (2013), Focused ultrasound propagation in water containing many therapeutical microbubbles, Paper OS6-04-4, Proc. of FLUCOME 2013, 12th Intern. Conf., Nara, Japan]Search in Google Scholar
[14. Kargbo D.M. (2010), Biodiesel production from municipal sewage sludges, Energy and Fuels, Vol. 24, 2791-2797.]Search in Google Scholar
[15. Kooiman K., Foppen-Harteveld M., Der Steen A.F.W.V., De Jong N.(2011), Sonoporation of endothelial cells by vibrating targeted microbubbles, Journal of Controlled Release, Vol. 154, 35-41..10.1016/j.jconrel.2011.04.00821514333]Search in Google Scholar
[16. Kuznetsova L.A., Coakley W.T. (2007), Applications of ultrasound streaming and radiation force in biosensors, Biosensors and Bioelectronics, Vol. 22, 1567-1572.]Search in Google Scholar
[17. Lam M.K., Lee K.T, (2012) Microalgae biofuels: a critical review of issues, problems and the way forward, Biotechnology Advances, Vol. 30, 673-678.]Search in Google Scholar
[18. Lee J.H., Lee K. H., Won J. M., Rhee K., Chung S. K. (2012), Mobile oscillating bubble actuated by AC-electrowetting-on-dielectric for microfluidic mixing enhancement, Sensors and Actuators A: Physical, Vol. 182, 153-162.]Search in Google Scholar
[19. Leite G.B., Abdelaziz A.E., Hallenbeck P.C. (2013), Algal biofuels: challenges and opportunities, Bioresource Technology, Vol. 145, 134-139.]Search in Google Scholar
[20. Madavan N.K., Deutsch S., Merkle C. L. (1984), Reduction of turbulent skin friction by microbubbles, Physics of Fluids, Vol.27, 356-363.]Search in Google Scholar
[21. McCormick M.E, Bhattacharyya R. (1973), Drag reduction of a submersible hull by electrolysis, Naval Engineers Journal, Vol. 85, 2973-2978.]Search in Google Scholar
[22. Moriguchi Y., Kato H. (2002), Influence of microbubble diameter and distribution on frictional resistance reduction, Journal of Marine Science and Technology, Vol. 7, 79-85.]Search in Google Scholar
[23. Oh J.S., Kwon Y. S., Lee K. H., Jeong W., Chung S. K., Rhee K. (2014), Drug perfusion enhancement in tissue model by steady streaming induced by oscillating micro-bubbles, Computers in Biology and Medicine, Vol. 44, 37-43]Search in Google Scholar
[24. Pang M.J., Wei J.J., Yu B. (2014), Numerical study on modulation of microbubbles on turbulence frictional drag in a horizontal channel, Ocean Engineering, Vol. 81, 58-64.]Search in Google Scholar
[25. Prevenslik T. (2011), Stability of nanobubbles by quantum mechanics, Proceedings of conference ‘Topical Problem of Fluid Mechanics’, Prague, 113-116.]Search in Google Scholar
[26. Rawat I., Ranjith Kumar R., Mutanda T., Bux F. (2011) Dual role of microalgae: phycoremediation of domestic wastewater and biomass production for sustainable biofuels production, Applied Energy, Vol. 88, 3411-3424.]Search in Google Scholar
[27. Rehman F., Medley G. J. D., Bandulasena H.C.H., Zimmerman W. B. (2015) Fluidic oscillator-mediated microbubble generation to provide cost effective mass transfer and mixing efficiency to the wastewater treatment plants, Environmental Research, Vol.137, 32-39.]Search in Google Scholar
[28. Rodríguez-Rodríguez J., Sevilla A., Martinez-Bazán C., Gordillo J. M. (2015), Generation of microbubbles with applications to industry and medicine, Annular Review of Fluid Mechanics, 405-429.10.1146/annurev-fluid-010814-014658]Search in Google Scholar
[29. Shams M.M., Dong M., Mahinpey N. (2014), Friction factor of microbubbles in capillary tubes at low Reynolds numbers, Chemical Engineering Science, Vol.112, 72-77.]Search in Google Scholar
[30. Sun R.R., Noble M. L., Sun S. S., Song S., Miao C. H. (2014), Development of therapeutic microbubbles for enhancing ultrasound-mediated gene delivery, Journal of Controlled Release, Vol. 182, 111-120.]Search in Google Scholar
[31. Terasaka K., Hirabayashi A., Nishino T., Fujioka S., Kobayashi D. (2011), Development of microbubble aerator for waste water treatment using aerobic activated sludge, Chemical Engineering Science, Vol. 66, 3172-3179.]Search in Google Scholar
[32. Tesař V., Tippetts J. R., Allen R. W. K., Low Y.-Y. (2005), Subdynamic asymptotic behavior of microfluidic valves, Journal of Microelectromechanical Systems, Vol. 14, 335-347.]Search in Google Scholar
[33. Tesař V. (2007), Configurations of fluidic actuators for generating hybrid-synthetic jet, Sensors and Actuators A: Physical, Vol. 138, 394-403.]Search in Google Scholar
[34. Tesař V. (2007), Fluidics applied to generating small aeration bubbles, Proc. of 9th Int. Symp. FLUCOME 2007, Tallahassee, FLA USA.]Search in Google Scholar
[35. Tesař V. (2009) Fluidic control of reactor flow – Pressure drop matching, Chemical Engineering Research and Design, Vol. 87, 817-832.]Search in Google Scholar
[36. Tesař V. (2009), Enhancing impinging heat or mass transgfer by fluidically generated flow pulsation, Chemical Engineering Research and Design, Vol. 87, 181-192.]Search in Google Scholar
[37. Tesař V. (2010), No-moving-part valve for automatic flow switching, Chemical Engineering Journal, Vol. 162, 278-295.]Search in Google Scholar
[38. Tesař V. (2013), Microbubble smallness limited by conjunctions, Chemical Engineering Journal, Vol. 231, 526-536.]Search in Google Scholar
[39. Tesař V. (2014), Microbubble generator excited by fluidic oscillators´s third harmonic frequency, Chemical Engineering Research and Design, Vol. 92, 1603-1615.]Search in Google Scholar
[40. Tesař V. (2014a) New concept: Low-pressure wide-angle atomiser, Chemical Engineering and Processing: Process Intensification, Vol. 82, 19-29.10.1016/j.cep.2014.05.004]Search in Google Scholar
[41. Tesař V. (2014b), Shape oscillation of microbubbles, Chemical Engineering Journal, Vol. 235, 368-378.10.1016/j.cej.2013.09.027]Search in Google Scholar
[42. Tesař V. (2015), Fluidic generator of microbubbles (in Czech), Czech Rep. Patent Application, PV 2015-204 filed March 2015.]Search in Google Scholar
[43. Tesař V., Hung C.-H., Zimmerman W.B.J. (2006), No-moving-part hybrid-synthetic jet actuator, Sensors and Actuators, A: Physical, Vol. 125, 159-169.]Search in Google Scholar
[44. Tesař V., Zhong S. (2003), Efficiency of Synthetic Jet Generation, Transactions of the Aeronautical and Astronautical Society of the Republic of China, Zhongguo Hangkong Taikong Xuehui Huikan, Vol. 35, 45-53.]Search in Google Scholar
[45. Tesař V., Zhong S., Fayaz R. (2013) New fluidic oscillator concept for flow separation control, AIAA Journal, Vol. 51, 397-405]Search in Google Scholar
[46. Trávníček Z., Tesař V., Kordk J. (2007), Performance of synthetic jet actuators based on hybrid and double-acting principles, Journal of Visualization, Vol.11, 221-l220.]Search in Google Scholar
[47. Tremblay-Darveau C., Williams R., Burns P.N. (2014), Measuring absolute blood pressure using microbubbles, Ultrasound in Medicine and Biology, Vol. 40, 775-781.]Search in Google Scholar
[48. Tsuge H., Li P., Shimatani N., Shimamura Y., Nakata H., Ohira M. (2009) Fundamental study on disinfection effect of microbubbles, Kagaku Kogaku Ronbunshu, Vol. 35, 548-552.]Search in Google Scholar
[49. Wang C., Yalikop S. V., Hilgenfeldt S. (2012), Efficient manipulation of microparticles in bubble streaming flows, Biomicrofluidics, Vol. 6, 012801]Search in Google Scholar
[50. Watanabe O., Masuko A., Shirose Y. (1998), Measurements of drag reduction by microbubbles using very long ship models, Journal of Soc. Naval Architects, Vol. 183, 53-59.10.2534/jjasnaoe1968.1998.53]Search in Google Scholar
[51. Watanabe Y., Aoi A., Horie S., Tomita N., Mori S., Morikawa H., Matsumura Y., Vassaux G., Kodama T. (2008), Low-intensity ultrasound and microbubbles enhance the antitumor effect of cisplatin, Cancer Science, Vol. 99, 2525-2531.]Search in Google Scholar
[52. Wataneabe K., (2013), Washing effect of microbubbles, Paper OS1-01-1, Proc. of FLUCOME 2013, 12th Intern. Conf., Nara, Japan, November 2013]Search in Google Scholar
[53. Xi X. (2012), Controlled translation and oscillation of microbubbles near a surface in an acoustic standing wave field, PhD Thesis, Mechanical Engineering Department, Imperial College London.]Search in Google Scholar
[54. Yanuar, Gunawan, Sunaryo, Jamaluddin A. (2012), Micro-bubble drag reduction on a high-speed vessel model, Journal of Marine Science and Technology, Vol. 17, 301-304.]Search in Google Scholar
[55. Zimmerman W.B., Tesař V., Butler S., Bandulasena H.C.H. (2008), Microbubble generation, Recent Patents in Engineering, Vol. 2, 1-8]Search in Google Scholar
[56. Zimmerman W.B., Al-Mashhadani M.K.H., Bandulasena H.C.H. (2013) Evaporation dynamics of microbubbles, Chemical Engineering Science, Vol. 101, 865-877.]Search in Google Scholar
[57. Zimmerman W.B., Zandi M., Bandulasena H.C.H. (2011), Towards energy efficient nanobubble generation with fluidic oscillation, Current Opinion in Colloid & Interface Science, Vol. 16, 350-356.]Search in Google Scholar
[58. Zimmerman W.B., Zandi M., Bandulasena H.C.H., Tesa5 V., Gilmour J.D., Ying K. (2011), Design of an airlift bioreactor and pilot scale studies with fluidic oscillator induced micro bubbles for growth of a microalgae Dunaliella Salina, Applied Energy, Vol. 88, 3357-3369.]Search in Google Scholar