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Surface tension, higher order phase field equations, dimensional analysis and Clairaut’s equation

  • Received: 11 October 2016 Accepted: 28 October 2016 Published: 28 March 2017
  • A higher order phase field free energy leads to higher order differential equations. The surface tension involves L2 norms of higher order derivatives. An analysis of dimensionless variables shows that the surface tension satisfies a Clairaut's equation in terms of the coeffcients of the higher order phase field equations. The Clairaut's equation can be solved by characteristics on a suitable surface in the $\mathbb{R}^N$ space of coeffcients. This perspective may also be regarded as interpreting dimensional analysis through Clairaut's equation. The surface tension is shown to be a homogeneous function of monomials of the coeffcients.

    Citation: Gunduz Caginalp. Surface tension, higher order phase field equations, dimensional analysis and Clairaut’s equation[J]. AIMS Mathematics, 2017, 2(2): 207-214. doi: 10.3934/Math.2017.2.207

    Related Papers:

  • A higher order phase field free energy leads to higher order differential equations. The surface tension involves L2 norms of higher order derivatives. An analysis of dimensionless variables shows that the surface tension satisfies a Clairaut's equation in terms of the coeffcients of the higher order phase field equations. The Clairaut's equation can be solved by characteristics on a suitable surface in the $\mathbb{R}^N$ space of coeffcients. This perspective may also be regarded as interpreting dimensional analysis through Clairaut's equation. The surface tension is shown to be a homogeneous function of monomials of the coeffcients.


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