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Citation:
 Dilip Das and B. N. Mandal.Construction of Wave-free Potential in the Linearized Theory of Water Waves[J].Journal of Marine Science and Application,2010,(4):347-354.
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Construction of Wave-free Potential in the Linearized Theory of Water Waves

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Title:
Construction of Wave-free Potential in the Linearized Theory of Water Waves
Author(s):
Dilip Das and B. N. Mandal
Affilations:
Author(s):
Dilip Das and B. N. Mandal
1. Shibpur Dhinbundhoo Institution (College), Department of Mathematics, 412/1 G. T. Road, Howrah-711102, India 2. Physics and Applied Mathematics Unit, Indian Statistical Institute, 203, B.T. Road, Kolkata 700 108, India
Keywords:
wave-free potential free surface surface tension ice-cover Laplace equation Helmholz equation
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DOI:
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Abstract:
Various water wave problems involving an infinitely long horizontal cylinder floating on the surface water were investigated in the literature of linearized theory of water waves employing a general multipole expansion for the wave potential. This expansion involves a general combination of a regular wave, a wave source, a wave dipole and a regular wave-free part. The wave-free part can be further expanded in terms of wave-free multipoles which are termed as wave-free potentials. These are singular solutions of Laplace’s equation (for non-oblique waves in two dimensions) or two-dimensional Helmholz equation (for oblique waves) satisfying the free surface condition and decaying rapidly away from the point of singularity. The method of constructing these wave-free potentials is presented here in a systematic manner for a number of situations such as deep water with a free surface, neglecting or taking into account the effect of surface tension, or with an ice-cover modelled as a thin elastic plate floating on water.

References:

Athanassonlis GA (1984). An expansion theorem for water- wave potentials. Journal of Engineering Mathematics, 18, 181-194.
 Bolton WE, Ursell F (1973). The wave force on an infinite long circular cylinder in an oblique sea. Journal of Fluid Mechanics, 57, 241-256.
 Das Dilip, Mandal BN (2009). Wave scattering by a circular cylinder half-immersed in water with an ice-cover. International Journal of Engineering Sciences, 47, 463-474.
 Gradshteyn IS, Ryzhik IM (1980). Table of Integrals, Series and Products. Academic Press Inc., Burlington.
Havelock TH (1955). Waves due to a floating sphere making periodic heaving oscillations. Proceedings of Royal Society London, London, A 231, 1-7.
 Linton CM, McIver P (2001). Handbook of mathematical techniques for wave/structure introductions. Chapman and Hall/CRC Boca Raton, 247-270.
 Mandal BN, Goswami SK (1984). Scattering of surface waves obliquely incident on a fixed half-immersed circular cylinder. Mathematical Proceedings of Cambridge Philosophical Society, Cambridge, 96, 359-369.
Rhodes-Robinson PF (1970). Fundamental singularities in the theory of water waves with surface tension. Bulletin of Australian Mathematical Society, 2, 317-333.
Thorne RC (1953). Multipole expansions in the theory of surfa-ce waves. Proceedings of Cambridge Philosophical Society, Cambridge, 49, 707-716.
Ursell F (1949). On the heaving motion of a circular cylinder on the surface of a fluid. Quarterly Journal of Mechanics and Applied Mathematics, 2, 218-231.
Ursell F (1961a). The transmission of surface waves under surface obstacles. Proceedings of Cambridge Philosophical Society, Cambridge, 57, 638-663.
Ursell F (1961b). Slender oscillating ships at zero forward speed. Journal of Fluid Mechanics, 14, 496-516.
 Ursell F (1968). The expansion of water wave potentials at great distances. Proceedings of Cambridge Philosophical Society, Cambridge, 64, 811-826.

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Last Update: 2011-04-29