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, specifically

general relativity General relativity, also known as the general theory of relativity, and as Einstein's theory of gravity, is the differential geometry, geometric theory of gravitation published by Albert Einstein in 1915 and is the current description of grav ...

, the Mathisson–Papapetrou–Dixon equations describe the motion of a massive spinning body moving in a

gravitational field In physics, a gravitational field or gravitational acceleration field is a vector field used to explain the influences that a body extends into the space around itself. A gravitational field is used to explain gravitational phenomena, such as ...

. Other equations with similar names and mathematical forms are the Mathisson–Papapetrou equations and Papapetrou–Dixon equations. All three sets of equations describe the same physics. These equations are named after Myron Mathisson, William Graham Dixon, and Achilles Papapetrou, who worked on them. Throughout, this article uses the

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''c'' = ''G'' = 1, and

tensor index notation In mathematics, a tensor is an algebraic object that describes a multilinear relationship between sets of algebraic objects associated with a vector space. Tensors may map between different objects such as vectors, scalars, and even other ...

Mathisson–Papapetrou–Dixon equations

The Mathisson–Papapetrou–Dixon (MPD) equations for a mass

m

spinning body are :

\begin
  \frac + \frac 12 S^ R_V^\rho &= 0, \\
              \frac + V^\lambda k^\mu - V^\mu k^\lambda &= 0.
\end

Here

\tau

is the proper time along the trajectory,

k_\nu

is the body's four-momentum :

k_\nu= \int_ _\nu \sqrt d^3 x,

the vector

V^\mu

is the four-velocity of some reference point

X^\mu

in the body, and the skew-symmetric tensor

S^

is the angular momentum :

S^ = \int_\left\ \sqrtd^3 x

of the body about this point. In the time-slice integrals we are assuming that the body is compact enough that we can use flat coordinates within the body where the energy-momentum tensor

T^

is non-zero. As they stand, there are only ten equations to determine thirteen quantities. These quantities are the six components of

S^

, the four components of

k_\nu

and the three independent components of

V^\mu

. The equations must therefore be supplemented by three additional constraints which serve to determine which point in the body has velocity

V^\mu

. Mathison and Pirani originally chose to impose the condition

V^\mu S_ = 0

which, although involving four components, contains only three constraints because

V^\mu S_V^\nu

is identically zero. This condition, however, does not lead to a unique solution and can give rise to the mysterious "helical motions". The Tulczyjew–Dixon condition

k_\mu S^ = 0

''does'' lead to a unique solution as it selects the reference point

X^\mu

to be the body's center of mass in the frame in which its momentum is

(k_0, k_1, k_2, k_3) = (m, 0, 0, 0)

. Accepting the Tulczyjew–Dixon condition

k_\mu S^=0

, we can manipulate the second of the MPD equations into the form :

\frac + \frac 1\left(S_ k_\mu \frac + S_ k_\lambda \frac\right) = 0,

This is a form of Fermi–Walker transport of the spin tensor along the trajectory – but one preserving orthogonality to the momentum vector

k^\mu

rather than to the tangent vector

V^\mu = dX^\mu/d\tau

. Dixon calls this ''M-transport''.

References

Notes

Selected papers

* * * * * * * * * * * * {{DEFAULTSORT:Mathisson-Papapetrou-Dixon equations Equations General relativity

Mathisson–Papapetrou–Dixon equations

See also

References

Notes

Selected papers