Multipole magnet explained

Multipole magnets are magnets built from multiple individual magnets, typically used to control beams of charged particles. Each type of magnet serves a particular purpose.

Dipole magnets are used to bend the trajectory of particles
Quadrupole magnets are used to focus particle beams
Sextupole magnets are used to correct for chromaticity introduced by quadrupole magnets^[1]

Magnetic field equations

The magnetic field of an ideal multipole magnet in an accelerator is typically modeled as having no (or a constant) component parallel to the nominal beam direction (

direction)and the transverse components can be written as complex numbers:^[2]

B_x+iB_y=C_n ⋅ (x-iy)^n-1

where

and

are the coordinates in the plane transverse to the nominal beam direction.

C_n

is a complex number specifying the orientation and strength of the magnetic field.

B_x

and

B_y

are the components of the magnetic field in the corresponding directions. Fields with a real

C_n

are called 'normal' while fields with

C_n

purely imaginary are called 'skewed'.

Stored energy equation

See main article: Magnetic energy.

For an electromagnet with a cylindrical bore, producing a pure multipole field of order

, the stored magnetic energy is:

U_n=

	n!²
	2n

\pi\mu₀\ellN²I².

Here,

\mu₀

is the permeability of free space,

\ell

is the effective length of the magnet (the length of the magnet, including the fringing fields),

is the number of turns in one of the coils (such that the entire device has

2nN

turns), and

is the current flowing in the coils. Formulating the energy in terms of

can be useful, since the magnitude of the field and the bore radius do not need to be measured.

Note that for a non-electromagnet, this equation still holds if the magnetic excitation can be expressed in Amperes.

Derivation

The equation for stored energy in an arbitrary magnetic field is:^[3]

	1
	2

\int\left(

	B²
	\mu₀

\right)d\tau.

Here,

\mu₀

is the permeability of free space,

is the magnitude of the field, and

d\tau

is an infinitesimal element of volume. Now for an electromagnet with a cylindrical bore of radius

, producing a pure multipole field of order

, this integral becomes:

U_n=

	1
	2\mu₀

\int^\ell\int

	2\pi

	0

B²d\tau.

Ampere's Law for multipole electromagnets gives the field within the bore as:^[4]

B(r)=

	n!\mu₀NI
	Rⁿ

r^n-1.

Here,

is the radial coordinate. It can be seen that along

the field of a dipole is constant, the field of a quadrupole magnet is linearly increasing (i.e. has a constant gradient), and the field of a sextupole magnet is parabolically increasing (i.e. has a constant second derivative). Substituting this equation into the previous equation for

U_n

gives:

U_n=

	1
	2\mu₀

\int^\ell\int

	2\pi
		\left(
	0

	n!\mu_0NI
	Rⁿ

r^n-1\right)²d\tau,

U_n=

	1
	2\mu₀

	R
\int		\left(
	0

	n!\mu_0NI
	Rⁿ

r^n-1\right)²(2\pi\ellrdr),

U_n=

	\pi\mu_0\elln!²N²I²
	R²ⁿ

	R
\int
	0

r^2n-1dr,

U_n=

	\pi\mu_0\elln!²N²I²
	R²ⁿ

\left(

	R²ⁿ
	2n

\right),

U_n=

	n!²
	2n

\pi\mu_0\ellN²I^2.

Notes and References

Web site: Varna 2010 | the CERN Accelerator School . https://web.archive.org/web/20170513010218/http://cas.web.cern.ch/cas/Bulgaria-2010/Talks-web/Brandt-1-web.pdf . 2017-05-13 . dead.
Web site: Wolski, Maxwell's Equations for Magnets – CERN Accelerator School 2009.
Book: Griffiths. David. Introduction to Electromagnetism. 2013. 4th. Pearson. Illinois. 329.
Book: Tanabe. Jack. Iron Dominated Electromagnets - Design, Fabrication, Assembly and Measurements. 2005. 4th. World Scientific. Singapore.