Three-dimensional analysis of the steady-state shape and small-amplitude oscillation of a bubble in uniform and non-uniform electric fields

S. M. LEE; I. S. KANG

doi:10.1017/S0022112098004133

Abstract

A three-dimensional analysis is performed to investigate the effects of an electric field on the steady deformation and small-amplitude oscillation of a bubble in dielectric liquid. To deal with a general class of electric fields, an electric field near the bubble is approximately represented by the sum of a uniform field and a linear field. Analytical results have been obtained for steady deformation and modification of oscillation frequency by using the domain perturbation method with the angular momentum operator approach.

It has been found that, to the first order, the steady shape of a bubble in an arbitrary electric field can be represented by a linear combination of a finite number of spherical harmonics Yml, where 0[les ]l[les ]4 and [mid ]m[mid ][les ]l. For the oscillation about the deformed steady shape, the overall frequency modification from the value of free oscillation about a spherical shape is obtained by considering two contributions separately: (i) that due to the deformed steady shape (indirect effect), and (ii) that due to the direct effect of an electric field. Both the direct and indirect effects of an electric field split the (2l+1)-fold degenerate frequency of Yml modes, in the case of free oscillation about a spherical shape, into different frequencies that depend on m. However, when the average is taken over the (2l+1) values of m, the frequency splitting due to the indirect effect via the deformed steady shape preserves the average value, while the splitting due to the direct effect of an electric field does not.

The oscillation characteristics of a bubble in a uniform electric field under the negligible compressibility assumption are compared with those of a conducting drop in a uniform electric field. For axisymmetric oscillation modes, deforming the steady shape into a prolate spheroid has the same effect of decreasing the oscillation frequency in both the drop and the bubble. However, the electric field has different effects on the oscillation about a spherical shape. The oscillation frequency increases with the increase of electric field in the case of a bubble, while it decreases in the case of a drop. This fundamental difference comes from the fact that the electric field outside the bubble exerts a suppressive surface force while the electric field outside the conducting drop exerts a pulling force on the surface.

Crossref Citations

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Lee, S. M. Im, D. J. and Kang, I. S. 2000. Circulating flows inside a drop under time-periodic nonuniform electric fields. Physics of Fluids, Vol. 12, Issue. 8, p. 1899.

Oh, J. M. Kim, P. J. and Kang, I. S. 2001. Chaotic oscillation of a bubble in a weakly viscous dielectric fluid under electric fields. Physics of Fluids, Vol. 13, Issue. 10, p. 2820.

Im, Do Jin and Kang, In Seok 2003. Electrohydrodynamics of a drop under nonaxisymmetric electric fields. Journal of Colloid and Interface Science, Vol. 266, Issue. 1, p. 127.

Elperin, T. Fominykh, A. and Orenbakh, Z. 2005. Simultaneous Convective Heat and Mass Transfer During Gas Bubble Dissolution in an Alternating Electric Field. Chemical Engineering Research and Design, Vol. 83, Issue. 10, p. 1237.

Spelt, P. D. M. and Matar, O. K. 2006. Collapse of a bubble in an electric field. Physical Review E, Vol. 74, Issue. 4,

Elperin, T. and Fominykh, A. 2006. Mass transfer during solute extraction from a fluid sphere with internal circulation in the presence of alternating electric field. Chemical Engineering and Processing: Process Intensification, Vol. 45, Issue. 7, p. 578.

Singh, Pushpendra and Aubry, Nadine 2007. Transport and deformation of droplets in a microdevice using dielectrophoresis. ELECTROPHORESIS, Vol. 28, Issue. 4, p. 644.

Kim, J. G. and Kang, I. S. 2007. CREEPING MOTION OF A BUBBLE WITH FIXED SURFACE CHARGE IN A UNIFORM ELECTRIC FIELD. Chemical Engineering Communications, Vol. 194, Issue. 10, p. 1342.

Kim, J.G. Im, D.J. Jung, Y.M. and Kang, I.S. 2007. Deformation and motion of a charged conducting drop in a dielectric liquid under a nonuniform electric field. Journal of Colloid and Interface Science, Vol. 310, Issue. 2, p. 599.

Oh, Jung Min Ko, Sung Hee and Kang, Kwan Hyoung 2008. Shape Oscillation of a Drop in ac Electrowetting. Langmuir, Vol. 24, Issue. 15, p. 8379.

Chen, Ping-Hei Lee, Ya-Wei and Chang, Tien-Li 2009. Predicting thermal instability in a closed loop pulsating heat pipe system. Applied Thermal Engineering, Vol. 29, Issue. 8-9, p. 1566.

Shaw, S. J. Spelt, P. D. M. and Matar, O. K. 2009. Electrically induced bubble deformation, translation and collapse. Journal of Engineering Mathematics, Vol. 65, Issue. 4, p. 291.

Hua, C.K. Lee, D.W. and Kang, I.S. 2010. Analyses on a charged electrolyte droplet in a dielectric liquid under non-uniform electric fields. Colloids and Surfaces A: Physicochemical and Engineering Aspects, Vol. 372, Issue. 1-3, p. 86.

Adamiak, K. and Floryan, J. M. 2010. Dynamics of Water Droplet Distortion and Break-Up in a Uniform Electric Field. p. 1.

Tran, Si Bui Quang Byun, Doyoung Yudistira, Hadi Teguh and Oh, Je Hoon 2011. Semianalytical study of hemispherical meniscus oscillation with an anchored edge on a conductive flat plate under an ac electric field. Physics of Fluids, Vol. 23, Issue. 2,

Adamiak, Kazimierz and Floryan, Jerzy M. 2011. Dynamics of Water Droplet Distortion and Breakup in a Uniform Electric Field. IEEE Transactions on Industry Applications, Vol. 47, Issue. 6, p. 2374.

Shirsavar, R. Amjadi, A. Ejtehadi, M. R. Mozaffari, M. R. and Feiz, M. S. 2012. Rotational regimes of freely suspended liquid crystal films under electric current in presence of an external electric field. Microfluidics and Nanofluidics, Vol. 13, Issue. 1, p. 83.

Shin, Young-Sub and Lim, Hee-Chang 2014. Shape Oscillation and Detachment of Droplet on Vibrating Flat Surface. Transactions of the Korean Society of Mechanical Engineers B, Vol. 38, Issue. 4, p. 337.

Yao, Ye Wang, Yechun and Beussman, Kevin M. 2014. Deformation and migration of a leaky-dielectric droplet in a steady non-uniform electric field. Microfluidics and Nanofluidics, Vol. 17, Issue. 5, p. 907.

Moon, Gi Jong Ahn, Myung Mo and Kang, In Seok 2015. Osmotic pressure of ionic liquids in an electric double layer: Prediction based on a continuum model. Physical Review E, Vol. 92, Issue. 6,

Download full list

Article contents

Three-dimensional analysis of the steady-state shape and small-amplitude oscillation of a bubble in uniform and non-uniform electric fields

Abstract

Access options

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Article contents

Three-dimensional analysis of the steady-state shape and small-amplitude oscillation of a bubble in uniform and non-uniform electric fields

Abstract

Access options

Save article to Kindle

Save article to Dropbox

Save article to Google Drive

Reply to: Submit a response

Your details

You have entered the maximum number of contributors

Conflicting interests