Dirichlet's ellipsoidal problem

In astrophysics, Dirichlet's ellipsoidal problem, named after Peter Gustav Lejeune Dirichlet, asks under what conditions there can exist an ellipsoidal configuration at all times of a homogeneous rotating fluid mass in which the motion, in an inertial frame, is a linear function of the coordinates. Dirichlet's basic idea was to reduce Euler equations to a system of ordinary differential equations such that the position of a fluid particle in a homogeneous ellipsoid at any time is a linear and homogeneous function of initial position of the fluid particle, using Lagrangian framework instead of the Eulerian framework.[1][2][3]

History

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In the winter of 1856–57, Dirichlet found some solutions of Euler equations and he presented those in his lectures on partial differential equations in July 1857 and published the results in the same month.[4] His work was left unfinished at his sudden death in 1859, but his notes were collated and published by Richard Dedekind posthumously in 1860.[5]

Bernhard Riemann said, "In his posthumous paper, edited for publication by Dedekind, Dirichlet has opened up, in a most remarkable way, an entirely new avenue for investigations on the motion of a self-gravitating homogeneous ellipsoid. The further development of his beautiful discovery has a particular interest to the mathematician even apart from its relevance to the forms of heavenly bodies which initially instigated these investigations."

Riemann–Lebovitz formulation

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Dirichlet's problem is generalized by Bernhard Riemann in 1860[6] and by Norman R. Lebovitz in modern form in 1965.[7] Let   be the semi-axes of the ellipsoid, which varies with time. Since the ellipsoid is homogeneous, the constancy of mass requires the constancy of the volume of the ellipsoid,

 

same as the initial volume. Consider an inertial frame   and a rotating frame  , with   being the linear transformation such that   and it is clear that   is orthogonal, i.e.,  . We can define an anti-symmetric matrix with this,

 

where we can write the dual   of   as   (and  ), where   is nothing but the time-dependent rotation of the rotating frame with respect to the inertial frame.

Without loss of generality, let us assume that the inertial frame and the moving frame coincide initially, i.e.,  . By definition, Dirichlet's problem is looking for a solution which is a linear function of initial condition  . Let us assume the following form,

 

and we define a diagonal matrix   with diagonal elements being the semi-axes of the ellipsoid, then above equation can be written in matrix form as

 

where  . It can shown then that the matrix   transforms the vector   linearly to the same vector at any later time  , i.e.,  . From the definition of  , we can realize the vector   represents a unit normal on the surface of the ellipsoid (true only at the boundary) since a fluid element on the surface moves with the surface. Therefore, we see that   transforms one unit vector on the boundary to another unit vector on the boundary, in other words, it is orthogonal, i.e.,  . In a similar manner as before, we can define another anti-symmetric matrix as

 ,

where its dual is defined as   (and  ). The Dirichlet's ellipsoidal problem then reduces to finding whether the matrix   exists that determines the vector   and that it is expressible in terms of two orthogonal matrices as in   where, further

 


Let   be the velocity field seen by the observer at rest in the moving frame, which can be regarded as the internal fluid motion since this excludes the uniform rotation seen by the inertial observer. This internal motion is found to given by

 

whose components, explicitly, are given by

 

These three components show that the internal motion is composed of two parts: one with a uniform vorticity   with components

 

and the other with a stagnation point flow, i.e.,  . Particularly, the physical meaning of   can be seen to be attributed to the uniform-vorticity motion. The pressure is found to assume a quadratic form, as derived by the equation of motion (and using the vanishing condition at the surface) given by

 

where   is the central pressure, so that  . Substituting this back in the equation of motion leads to

 

where   is the gravitational constant and   is diagonal matrix, whose diagonal elements are given by

 

The tensor momentum equation and the conservation of mass equation, i.e.,   provides us with ten equations for the ten unknowns,  

Dedekind's theorem

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It states that if a motion determined by   is admissible under the conditions of Dirichlet's problem, then the motion determined by the transpose   of   is also admissible. In other words, the theorem can be stated as for any state of motions that preserves a ellipsoidal figure, there is an adjoint state of motions that preserves the same ellipsoidal figure.

By taking transpose of the tensor momentum equation, one sees that the role of   and   are interchanged. If there is solution for  , then for the same  , there exists another solution with the role of   and   interchanged. But interchanging   and   is equivalent to replacing   by  . The following relations confirms the previous statement.

 

where, further

 

The typical configuration of this theorem is the Jacobi ellipsoid and its adjoint is called as Dedekind ellipsoid, in other words, both ellipsoid have same shape, but their internal fluid motions are different.

Integrals

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The tensor momentum equation admits three integrals, with regards to conservation of energy, angular momentum and circulation. The energy integral is found to be[1]

 

where

 

Next, we have the integral

 

which signifies the conservation of  , where the angular momentum components are given by

 

wherein   is the total mass. Since the problem is invariant to the interchange of   and  , from the above integral, we obtain

 

where we substituted the formula for   in terms of the vorticity vector  . This integral signifies the conservation of  , where the circulation components (in the inertial frame) are given by

 

See also

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References

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  1. ^ a b Chandrasekhar, S. (1969). Ellipsoidal figures of equilibrium (Vol. 10, p. 253). New Haven: Yale University Press.
  2. ^ Chandrasekhar, S. (1967). Ellipsoidal figures of equilibrium—an historical account. Communications on Pure and Applied Mathematics, 20(2), 251–265.
  3. ^ Lebovitz, N. R. (1998). The mathematical development of the classical ellipsoids. International journal of engineering science, 36(12), 1407–1420.
  4. ^ Dirichlet G. Lejeune, Nach. von der König. Gesell. der Wiss. zu Gött. 14 (1857) 205
  5. ^ Dirichlet, P. G. L. (1860). Untersuchungen über ein Problem der Hydrodynamik (Vol. 8). Dieterichschen Buchhandlung.
  6. ^ Riemann, B. (1860). Über die Fortpflanzung ebener Luftwellen von endlicher Schwingungsweite. Verlag der Dieterichschen Buchhandlung.
  7. ^ Norman R. Lebovitz (1965), The Riemann ellipsoids (lecture notes, Inst. Ap., Cointe-Sclessin, Belgium)