Hughes, W., Hughes, A.R., Liquid drops on the same liquid surface. Nature, 129, 1932, 59.
Stong, C.L., The amateur scientist. Sci Am 230:4 (1974), 116–122.
Iida, Y., Takashima, T., Direct-contact heat transfer characteristics: evaporation of a drop dropped onto a hot liquid surface. Int J Heat Mass Transfer 23:9 (1980), 1263–1271.
Nosoko, T., Mori, Y., Vaporization of drops of a denser, volatile liquid dropped onto a surface of another liquid. Trans ASME 107 (1985), 384–391.
Johansen, K., Kotopoulis, S., Postema, M., Ultrasonically driven antibubbles encapsulated by newtonian fluids for active leakage detection. Proceedings of the international multiconference of engineers and computer scientists, vol II, 2015, 1–5.
Kotopoulis, S., Johansen, K., Gilja, O., Poortinga, A., Postema, M., Acoustically active antibubbles. Acta Phys Pol A 127:1 (2015), 99–102.
Postema, M., Novell, A., Sennoga, C., Poortinga, A.T., Bouakaz, A., Harmonic response from microscopic antibubbles. Appl Acoust 137 (2018), 148–150.
Silpe, J.E., McGrail, D.W., Magnetic antibubbles: formation and control of magnetic macroemulsions for fluid transport applications. J Appl Phys, 113(17), 2013, 17B304.
Dorbolo, S., Caps, H., Vandewalle, N., Fluid instabilities in the birth and death of antibubbles. New J Phys, 5(1), 2003, 161.
Kim, P.G., Stone, H.A., Dynamics of the formation of antibubbles. Europhys Lett, 83, 2008, 54001.
Tufaile, A., Sartorelli, J.C., Bubble and spherical air shell formation dynamics. Phys Rev E, 66, 2002, 056204.
Postema, M., ten Cate, F., Schmitz, G., de Jong, N., van Wamel, A., Generation of a droplet inside a microbubble with the aid of an ultrasound contrast agent: first result. Lett Drug Des Discov 4:1 (2007), 74–77.
Poortinga, A.T., Micron-sized antibubbles with tunable stability. Colloids Surf A Physicochem Eng Asp 419 (2013), 15–20.
Silpe, J.E., Nunes, J.K., Poortinga, A.T., Stone, H.A., Generation of antibubbles from core-shell double emulsion templates produced by microfluidics. Langmuir 29 (2013), 8782–8787.
Shen, Y., Hu, L., Chen, W., Xie, H., Fu, X., Drop encapsulated in bubble: a new encapsulation structure. Phys Rev Lett, 120, 2018, 054503.
Bai, L., Xu, W., Wu, P., Lin, W., Li, C., Xu, D., Formation of antibubbles and multilayer antibubbles. Colloids Surf A Physicochem Eng Asp 509 (2016), 334–340.
Beilharz, D., Guyon, A., Li, E., Thoraval, M., Thoroddsen, S., Antibubbles and fine cylindrical sheets of air. J Fluid Mech, 779, 2015, 87.
Dorbolo, S., Reyssat, E., Vandewalle, N., Quéré, D., Aging of an antibubble. EPL (Europhys Lett), 69(6), 2005, 966.
Suhr, W., Gaining insight into antibubbles via frustrated total internal reflection. Eur J Phys, 33(2), 2012, 443.
Kim, P.G., Vogel, J., Antibubbles: factor that affects their stability. Coll Surf A 289 (2006), 237–244.
Zou, J., Wang, W., Ji, C., Bouncing antibubbles. Exp Fluids, 57(9), 2016, 147.
Zou, J., Ji, C., Yuan, B., Ruan, X., Fu, X., Collapse of an antibubble. Phys Rev E, 87(6), 2013, 061002.
Sob'yanin, D.N., Theory of the antibubble collapse. Phys Rev Lett, 114(10), 2015, 104501.
Dorbolo, S., Terwagne, D., Delhalle, R., Dujardin, J., Huet, N., Vandewalle, N., et al. Antibubble lifetime: influence of the bulk viscosity and of the surface modulus of the mixture. Colloids Surf A Physicochem Eng Asp 365 (2010), 43–45.
Golemanov, K., Denkov, N.D., Tcholakova, S., Vethamuthu, M., Lips, A., Surfactant mixtures for control of bubble surface mobility in foam studies. Langmuir, 24, 2008, 9956.
Scheid, B., Dorbolo, S., Arriaga, L.R., Rio, E., Antibubble dynamics: the drainage of an air film with viscous interfaces. Phys Rev Lett, 109, 2012, 264502.
Emile, J., Salonen, A., Dollet, B., Saint-Jalmes, A., A systematic and quantitative study of the link between foam slipping and interfacial viscoelasticity. Langmuir 25 (2009), 13412–13418.
Lin, S.-Y., Lee, Y.-C., Shao, M.-J., Adsorption kinetics of C12E6 at the air-water interface. J Chin Inst Chem Engrs, 33, 2002, 631.
Zell, Z.A., Nowbahar, A., Mansard, M., Leal, L.G., Deshmukh, S.S., Mecca, J.M., et al. Surface shear inviscidity of soluble surfactants. Proc Nat Am Soc 111:10 (2014), 3677–3682.
Scheid, B., Zawala, J., Dorbolo, S., Gas dissolution in antibubble dynamics. Soft Matter 10 (2014), 7096–7102.
Champougny, L., Scheid, B., Restagno, F., Vermant, J., Rio, E., Surfactant-induced rigidity of interfaces: a unified approach to free and dip-coated films. Soft Matter 11:14 (2015), 2758–2770.
Stone, H.A., A simple derivation of the time-dependent convective-diffusion equation for surfactant transport along a deforming interface. Phys Fluids A 2:1 (1990), 111–112.
Battino, R., Rettich, T.R., Tominaga, T., The solubility of nitrogen and air in liquids. J Phys Chem Ref Data Monogr, 13(2), 1984, 563.
Stubenrauch, C., Rojas, O.J., Schlarmann, J., Claesson, P.M., Interactions between nonpolar surfaces coated with the nonionic surfactant hexaoxyethylene dodecyl ether C12e6 and the origin of surface charges at the air/water interface. Langmuir 20:12 (2004), 4977–4988.
Fainerman, V.B., Lylyk, S.V., Aksenenko, E.V., Makievski, A.V., Petkov, J.T., Yorke, J., et al. Adsorption layer characteristics of triton surfactants: 1. Surface tension and adsorption isotherms. Colloids Surf A Physicochem Eng Asp 334 (2009), 1–7.
Wantke, K.-D., Fruhner, H., Fang, J., Lunkenheimer, K., Measurements of the surface elasticity in medium frequency range using the oscillating bubble method. J Colloid Interface Sci 208:1 (1998), 34–48.
Cheng, N.-S., Formula for the viscosity of a glycerol? Water mixture. Ind Eng Chem Res 47 (2008), 3285–3288.
Volk, A., Kähler, C.J., Density model for aqueous glycerol solutions. Exp Fluids, 59(5), 2018, 75.
Bhamla, M.S., Giacomin, C.E., Balemans, C., Fuller, G.G., Influence of interfacial rheology on drainage from curved surfaces. Soft Matter 10 (2014), 6917–6925.
Matsumoto, Y., Uda, T., Takagi, S., The effect of surfactant on rising bubbles. Balachandar, S., Prosperetti, A.e., (eds.) IUTAM symposium on computational approaches to multiphase flow. fluid mechanics and its applications, vol. 81, 2006, Springer, Dordrecht, 311–321.
Allen, H., On the motion of a sphere in a viscous fluid. Phil Mag 50 (1900), 323–338.
Turton, R., Levenspiel, O., A short note on the drag correlation for spheres. Powder Technol 47 (1986), 83–86.
Brown, P., Lawler, D.F., Sphere drag and settling velocity revisited. J Environ Eng 129 (2003), 222–231.
Denkov, N.D., Marinova, K.G., Tcholakova, S.S., Mechanistic understanding of the modes of action of foam control agents. Adv Colloid Interface Sci 206 (2014), 57–67.
Sánchez, A. Evangelio, Generacion controlada de microburbujas y microemulsiones. Estabilidad de burbujas en interfases. PhD Thesis, 2016, Universidad de Sevilla.
Tittarelli, A., Borgini, A., Bertoldi, M., De Saeger, E., Ruprecht, A., Stefanoni, R., et al. Estimation of particle mass concentration in ambient air using a particle counter. Atmos Environ 42 (2008), 8543–8548.
Morawska, L., He, C., Hitchins, J., Gilbert, D., Parappukkaran, S., The relationship between indoor and outdoor airborne particles in the residential environment. Atmos Environ 35 (2001), 3463–3473.
Charles, G., Mason, S., The coalescence of liquid drops with flat liquid/liquid interfaces. J Colloid Sci 15:3 (1960), 236–267.
Dorbolo, S., Antibubble observed with monochromatic light (bottom view). URL https://youtu.be/JtrTpEmJZsA, Nov 2009.
Mysels, K.J., Shinoda, K., Frankel, S., Soap films: studies of their thinning and a bibliography. 1959, Pergamon, New York.
Bruinsma, R., Theory of hydrodynamic convection in soap films. Physica A: Statistical Mechanics and its Applications 216:1 (1995), 59–76.
Kamp, J., Villwock, J., Kraume, M., Drop coalescence in technical liquid/liquid applications: a review on experimental techniques and modeling approaches. Rev Chem Eng 33:1 (2017), 1–47.
Lorenceau, E., Quéré, D., Eggers, J., Air entrainment by a viscous jet plunging into a bath. Phys Rev Lett, 93(25), 2004, 254501.
de Gennes, P.-G., Brochart-Wyart, F., Quéré, D., Gouttes, Bulles, Perles et Ondes. Belin (Paris), 2005.
Quéré, D., Fluid coating on a fiber. Annu Rev Fluid Mech 31:1 (1999), 347–384.
Charru, F., Hydrodynamic instabilities. 2011, Cambridge University Press.