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I am asking whether the following Lagrangian for a point moving in a conservative field, can be correct :

$L(r, v, \omega) = \frac {mv^2}{2} + \frac {I \omega^2}{2} - U(r)$.

$r$ is the distance between the equipotential surface on which the movement begins and the equipotential surface on which the movement ends, $v = \text d r/ \text d t$, $\omega$ is angular velocity of rotation around some fix point in space (see example on the bottom of the text), $I = m\rho^2$, where $\vec \rho$ is the vector connecting the fix point in the space with the current position of the moving point (see the example).

What I am not sure on, is the presence of the term $I \omega^2/2$. I think that $\omega $ can vary only if the potential energy can produce a torque ($\vec F \ \text x \ \vec \rho$), and in that case $U$ should also depend on a variable $\theta$, indicating the angle between the vector $\vec \rho$ and a fix axis in the rotation plane.

But, if there is a torque, if $U$ depends not only on the distance between equipotential surfaces, but also on an angle $\theta$, is this anymore a conservative field? I know that in a conservative field the mechanical work doesn't depend on the path followed by the point, but on the distance between equipotential surfaces, however that doesn't help me in my question.

(As a simple example, one can think that the field is produced by an electric charge uniformly distributed on an ellipsoid. Then $d$ is the distance to the surface of the ellipsoid measured perpendicularly on the equipotential surfaces, and given a point $P$ in the field, $\vec \rho$ is the vector from the center of the ellipsoid to the pint $P$.)

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  • $\begingroup$ Strictly speaking, that $\frac{I\omega^2} 2$ term should be $\frac 1 2 \omega \cdot (I\omega)$. Moment of inertia is a tensor quantity. $\endgroup$ – David Hammen Jan 19 '15 at 0:25
  • $\begingroup$ @DavidHammen but my moving object is a point, not an object with some volume. Well, I hope to "meet" you tomorrow. $\endgroup$ – Sofia Jan 19 '15 at 0:27
  • $\begingroup$ Classically, the moment of inertia of a point mass is zero. That term vanishes for a point mass. $\endgroup$ – David Hammen Jan 19 '15 at 2:21
  • $\begingroup$ @DavidHammen no, David, that term doesn't express spin of the point around itself, but around an external point, see the example with the ellipsoid. I also feel that the potential $U$ has to contain a variable $\theta$, after all $\omega$ is the derivative of $\theta$. $\endgroup$ – Sofia Jan 19 '15 at 11:11
  • $\begingroup$ @DavidHammen my worry is that if $U$ depends on an angle $\theta$ and there is also a torque, then the field is no more conservative. What you say? $\endgroup$ – Sofia Jan 19 '15 at 11:50
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The answer to the title of this question, "Can a conservative field produce a torque?" is yes. For example, a non-uniform gravity field (e.g., the Earth's gravity field) results in a gravity gradient torque on an object with a non-spherical mass distribution. This torque is sometimes problematic for artificial satellites, other times something those satellites can take advantage of as a stabilizing influence.

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  • $\begingroup$ Hi! How are you? I was pretty convinced that the answer is negative. What you say is an interesting surprise. Now I am going to sleep, but tomorrow maybe you can find some time and tell me more. $\endgroup$ – Sofia Jan 19 '15 at 0:22
  • $\begingroup$ Something similar happens in fluid mechanics - e.g. a dumb-bell in a plane strain $\vec{u}\sim \vec{x}$ (Landau and Lifshitz 1959, $\S$ 11). $\endgroup$ – Nick P Jan 19 '15 at 1:43
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I'm not sure about the notation, so there will be a bit of guessing here. I assume $v = \dot r$, so the kinetic term can be interpreted to be that of a point moving on a plane, described by polar coordinates. Now take any radial potential, which by the rotational symmetry generates a central field. Let us consider Kepler's problem to be definite here. It is well known that closed orbits are elliptic in general, hence $\omega$ is not constant throughout the motion, but $\mathbf F\times\mathbf r = 0$ at every time.

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  • $\begingroup$ it's not a central field here. This is my problem. Assume that the conservative field is generated by a charge uniformly distributed on an ellipsoid. $\endgroup$ – Sofia Jan 18 '15 at 23:07
  • $\begingroup$ your potential is invariant under rotations... $\endgroup$ – Phoenix87 Jan 18 '15 at 23:09
  • $\begingroup$ that edit changes things and that fixed point breaks rotation invariance. I'm not even sure you can regard that kinetic part as a valid one. $\endgroup$ – Phoenix87 Jan 18 '15 at 23:16
  • $\begingroup$ "where ρ is the distance to some fix point in the space." Unless the fixed point is the origin, i.e. $\rho = 0$ implies $r = 0$, this fixed point breaks the rotational symmetry around the "origin". $\endgroup$ – Phoenix87 Jan 18 '15 at 23:20
  • $\begingroup$ Let us continue this discussion in chat. $\endgroup$ – Phoenix87 Jan 18 '15 at 23:25

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