Quantitative Analysis of Secondary Bjerknes Forces in Various Liquids

[1] Simaciu I., Borsos Z., Dumitrescu Gh., Silva G.T. and Bărbat T., Acoustic scattering-extinction cross section and the acoustic force of electrostatic type, arXiv:1711.03567V2, 2017. Search in Google Scholar

[2] Simaciu I., Dumitrescu Gh. and Borsos Z., Acoustic force of the gravitational type, arXiv:1905.03622, 2019. Search in Google Scholar

[3] Simaciu I., Borsos Z. and Dumitrescu Gh., Acoustic gravitational interaction revised, arXiv:2206.00435v1, 2022. Search in Google Scholar

[4] Simaciu I., Dumitrescu Gh., Borsos Z., Baciu A. and Nan G., Acoustic Scattering-Absorption Cross Section of Electrostatic Type, Buletinul Institutului Politehnic din Iaşi, Secţia Matematică. Mecanică Teoretică. Fizică, Volumul 65 (69), No. 2, 29-38, 2019. Search in Google Scholar

[5] Jackson J.D., Classical Electrodynamics, Second Edition (2nd Edition), Wiley, New York, 1975. Search in Google Scholar

[6] Simaciu I., Borsos Z., Drafta V. and Dumitrescu Gh., Electrostatic Interaction in Stochastic Electrodynamics, Buletinul Institutului Politehnic din Iaşi, Secţia Matematică. Mecanică Teoretică. Fizică, Vol. 65 (69), No. 2, 29-38, 2022; arXiv:2106.04401v1. Search in Google Scholar

[7] Simaciu I., Borsos Z., Dumitrescu Gh. and Drafta V., Gravitational Interaction Mediated by Classical Zero Point Field, Buletinul Institutului Politehnic din Iaşi, Secţia Matematică. Mecanică Teoretică. Fizică, Vol. 68 (72), No. 3, 29-38, 2022; arXiv:2106.05849. Search in Google Scholar

[8] Simaciu I., Dumitrescu Gh. and Borsos Z., Mach’s Principle in the Acoustic World, Buletinul Institutului Politehnic din Iaşi, Secţia Matematică. Mecanică Teoretică. Fizică, Vol. 67 (71), No. 4, 59-69, 2021; arXiv: 1907.05713. Search in Google Scholar

[9] Doinikov A.A., Translational motion of two interacting bubbles in a strong acoustic field, Physical Review E, Vo. 64, 0263XX, 2001. Search in Google Scholar

[10] Klaasen B., Verhaeghe F., Blanpain B., Fransaer J., A study of gas bubbles in liquid mercury in a vertical Hele-Shaw cell, Exp. Fluids, vol. 55: 1652, 2014. Search in Google Scholar

[11] Donnelly R.J. Barenghi C.F., The Observed Properties of Liquid Helium at the Saturated Vapor Pressure, Journal of Physical and Chemical Reference Data 27, 1217-1274, 1998, https://doi.org/10.1063/1.556028. Search in Google Scholar

[12] Arp V.D., McCartyR.D., Friend D.G., Thermophysical Properties of Helium-4 from 0.8 to 1500 K with Pressures to 2000 MPa, NIST Technical Note 1334 (revised), 1998. Search in Google Scholar

[13] Noga R., De Prada C., First principles modeling of the Large Hadron Collider’s (LHC) Superfluid Helium Cryogenic Circuit, Proceedings of 20th European Modeling and Simulation Symposium (EMSS08), 2008. Search in Google Scholar

[14] Brooks J.S. and Donnelly R.J., The calculated thermodynamic properties of superfluid helium-4, J. Phys. Chem. Ref. Data, 6 (1), 51-104, 1977. Search in Google Scholar

[15] Eddington A.S., Preliminary Note on the Masses of the Electron, the Proton, and the Universe, Mathematical Proceedings of the Cambridge Philosophical Society, 27 (1), pp. 15-19, 1931. Search in Google Scholar

[16] Dirac P.A.M., The Large numbers hypothesis and the Einstein theory of gravitation, Proc. R. Soc. London, Ser. A 365, 19-30, 1979. Search in Google Scholar

[17] de la Peña L., Cetto A.M., Estimate of Planck’s Constant from an Electromagnetic Mach Principle, Foundations of Physics Letters 10 (6), pp. 591-598, 1997. Search in Google Scholar