Momentum compaction explained

The momentum compaction or momentum compaction factor is a measure for the momentum dependence of the recirculation path length for an object that is bound in cyclic motion (closed orbit). It is used in the calculation of particle paths in circular particle accelerators (like synchrotrons), and for astronomical objects that are bound by gravitation.

For a perturbed orbit, the momentum compaction factor is defined as the derivative of normalized path length difference to normalized momentum[1] [2]

\alphap=

dL/L
dp/p

=

p
L
dL=
dp
1
L

\oint

Dx(s)
\rho(s)

ds

.

Furthermore, the momentum compaction is closely connected to the so-called slip-factor[3]

η

with the horizontal dispersion

Dx

and the gyroradius

\rho

\alphap=

1
\gamma2

wherein

\gamma

is the Lorentz factor.

Notes and References

  1. Book: Conte . Mario . McKay . William W. . An Introduction to the Physics of Particle Accelerators . . 2nd . Apr 2008 . 978-981-277-961-8 .
  2. Book: Minty. Michiko G.. Zimmermann. Frank. Measurement and Control of Charged Particle Beams. 2003. Springer-Verlag. Berlin, Heidelberg, New York. 978-3-540-44187-8. 159.
  3. Book: Steinhagen . R. J. . CERN Accelerator School Beam Diagnostics / Tune and chromaticity diagnostics . . August 2009 . 343 . Daniel Brandt.

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