Introduction to Accelerator Science: Overview of Colliders ... · Transport and Betatron...
Transcript of Introduction to Accelerator Science: Overview of Colliders ... · Transport and Betatron...
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Introduction to Accelerator Science:
Overview of Colliders with Focus on RHIC
Waldo MacKay 1
RHIC/AGS Users’ Mtg: Intro to CollidersWaldo MacKay 3 June, 2009
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• longitudinal acceleration: radio frequencey cavities• transverse motion
• bending and focusing• Hamiltonian, variables• Equations of motion• Courant-Snyder functions, invariant, emittances• Tunes• Liouville’s Theorem• dispersion function• transverse beam size• nonlinearities, chromaticity
• longitudinal motion, acceleration, ...• phase stability• momentum compaction• transition energy
• Luminosity• low-β interaction region• beam-beam interaction, tune shift
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Why collide?
• To get to higher energy in the center of mass, of course.
A+B → X
M2cm = s = (PA + PB)µ(PA + PB)µ
• fixed target (B): sft = (EA +MB)2 − P 2B ∼ 2EAMB
assuming EA MA.
• head-on collisions: sc = (EA +EB)2 − (~PA + ~PB)2 ∼ 4EAEB
assuming also that EB MB as well.
RHIC: 250 GeV×250 GeV protons√s = 500 GeV.
Equivalent fixed target would require a beam of 133 TeV protons.
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Some types of colliders
• Linear colliders e+ + e− (SLC)
• Particle+anti-particle with a single ring• e+ + e−: many examples (SPEAR, VEPP4, LEP, CESR, ...)• p + p (Tevetron, SPPS)
• Dual rings: (ISR, B-factories, HERA, RHIC, LHC)• Not restricted to same species for each beam, or the same energy.
• Future possibilities include:• Another electron+hadron collider• Linear collider for e+ + e− in the TeV range• Muon collider
Disclaimer: The list of examples is not meant to be exhaustive.
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Acceleration with RF cavities
+ - ++ + +
+ ++++ - -
- - -
-- -
-
Linac: ~F = q ~E(t). Ring with rf cavity
• Must maintain synchronism of bunch with rf phase.
• Particles oscillate in energy about the stable synchronous phase.
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Particle Trajectories in Magnetic Fields
Dipole magnets bend the beamaround the ring.
B
p
proton
q=+1
F
Bend magnet (dipole)
Field out of screen
ρ = pqB⊥
Charged particles are deflected bymagnetic fields. Lorentz Force:
~F =q
γm~p× ~B
Quadrupole magnets focus thebeam for stability.
MagneticField
Protons moving into screen
S
N
N
S
Magnetic Lens (quadrupole)
Force
Vertically focusing
Horizontallydefocusing
∂By
∂x=∂Bx
∂y
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Momentum compaction and transition
• Momentum compaction: αp = dLL
/
dpp
, L is ring’s circumference.
ωrev =2π
τ=
2πβc
Ldωrev
ωrev
= −dτrevτrev
=dβ
β− dL
L=
(
1
γ2− αp
)
dp
p
• Phase slip factor: ηph = γ−2 − αp, γt = 1/√αp (RHIC: γt ∼ 23)
• Transition energy: Utr = mc2
√αp
, when ηph = 0.
• Below transition: velocity increase dominates (dβ/β).• Above transition: particle is relativistic (β close to c),
momentum compaction dominates (dL/L).
• Homework: Show that the momentum compaction of Earth is −2.
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Longitudinal equation of motion
φ+ωrfηphqV
2πβ2γmc2(sinφ− sinφs) = 0
ωrf = hωrev
• φ is the rf phase of the beam particle when it crosses the cavity.
• h is harmonic number.• RHIC: h =360 for 28 Mhz, or 7 × 360 = 2520 for 197 MHz.
• q, m are charge and mass of beam particle.
• V is the peak voltage of the rf cavity.
E(s, t) = V sin(ωrft+ φs)∞∑
n=−∞δ(s− nL)
• for fixed energy the synchronous phase φs = 0.
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Longinutinal motion above transition
ϕs ϕs+2π
τ+|dτ|τ
τ−|dτ|
Vrf
ϕ=ωrft
• Illustrated for harmonic number h = 1.
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Small oscillations and synchrotron frequency
Linearize Eq. of motion for small amplitudes:
φ = φs + ϕ
0 ' ϕ+ Ω2sϕ
• Angular synchrotron frequency: Ωs = ωrev
√
hηph cos φs
2πβ2γqVmc2
• In general |Ωs| 1.
• Synchotron tune: Qz = Ωs
ωrev
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-0.5
-0.4
-0.3
-0.2
-0.1
0
0.1
0.2
0.3
0.4
0.5
0.6
-4 -3 -2 -1 0 1 2 3 4
W=
−∆U
/ωrf
[eV
s]
φ
-0.4
-0.3
-0.2
-0.1
0
0.1
0.2
0.3
0.4
-3 -2 -1 0 1 2 3
W=
−∆U
/ωrf
[eV
s]
φ
-0.4
-0.3
-0.2
-0.1
0
0.1
0.2
0.3
0.4
-3 -2 -1 0 1 2 3
W=
−∆U
/ωrf
[eV
s]
φ
-0.4
-0.3
-0.2
-0.1
0
0.1
0.2
0.3
0.4
-3 -2 -1 0 1 2 3
W=
−∆U
/ωrf
[eV
s]
φ
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Hamiltonian
H(X,PX , Y, PY , Z, PZ ; t) =
√
(~P − q ~A)2 +m2c4 + qφ
After a bunch of canonical transformations and φ = 0, ~A = (0, 0, As):
H(x, x′, y, y′, z, δp/p0; s) ' − q
p0
As −(
1 +x
ρ
)(
1 +δp
p0
− 1
2(x′2 + y′2) + · · ·
)
s= ρθρ
xz
y
Z
X
Y
Design trajectory coordinate systemLocal traveling
Fixed lab coordinatesystem
θ
ρ =p
qB⊥
x′ =dx
ds
y′ =dy
ds
Paraxial approx.: |x′|, |y′| 1
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Paraxial coordinates
Expand about the design trajectory.
s= ρθρ
xz
y
Z
X
Y
Design trajectory coordinate systemLocal traveling
Fixed lab coordinatesystem
θ
x′ =dx
ds' dpx
p0
y′ =dy
ds' dpy
p0
z = s− v0t
δ =∆p
p0
~X =
xx′
yy′
zδ = ∆p
p0
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Hill’s Equations
x′′ + kx(s)x =δ
ρ(s),
y′′ + ky(s)y = 0,
with δ =∆p
p0
.
For quadrupoles:
kx =q
p
∂By
∂x
ky = −qp
∂By
∂x
Harmonic oscillator with periodic spring constant.
Periodic conditions: kj(s+ L) = kj(s), ρ(s+ L) = ρ(s)
where L is length of periodic cell.
• Horizontal motion has inhomogeneous dispersion term. Ignore it for now.
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Solutions to Hill’s Equation
Use Floquet’s (Block’s) Theorem ⇒Quasi-periodic solutions of form:
x(s) =√
Wβ(s) cos(ψ(s)), with
ψ′(s) =1
β(s).
Periodicity of β-function: β(s+ L) = β(s).
Note: In general ψ(s+ L) 6= ψ(s) + n2π. Resonances are bad!
x′(s) = −√
Wβ
[α(s) cosψ(s) + sinψ(s)] ,
with α(s) = − 12β′, and so α(s+ L) = α(s).
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Courant–Snyder Invariant
For a particular trajectory with initial conditions:
• Solve for sinψ and cosψ from equations for x and x′.
• Use sin2 ψ + cos2 ψ = 1 to get an invariant:
W =1
β
[
y2 + (αy + βy′)2]
(Action variable: J = 12W)
• Functions of s: y(s), y′(s), β(s), α(s). (β and α are periodic.)
• Eq. (1) is the equation for an ellipse.• Area of ellipse = πW.
• Beam envelope: ±√
β(s)εrms
• πεrms is the rms emittance
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Transport and Betatron Oscillations
FODO: Alternate focusing and defocusing lenses for stability.
Horizontal Betatron Oscillationwith tune: Qh = 6.3,
i.e., 6.3 oscillations per turn.
Vertical Betatron Oscillationwith tune: Qv = 7.5,
i.e., 7.5 oscillations per turn.
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2d Phase Space Plots
Horizontal Betatron Oscillationwith tune: Qx = 3.28,tracked through 10 turnswith 8 periodic cells.
x
x’
Ellipse area = πW =
∮
x′ dx
' 1
p0
∮
px dx
Poincare plot of particle on suc-cessive turns for one location inthe ring.
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Liouville’s Theorem
• Most beams have a low enough density, so that we ignore hard collisionsbetween particles.• Thus we can use a 6d phase space rather than a 6N-d phase space.
• In the phase space of coordinates and their corresponding canonical mo-menta, the phase flow of the particle trajectories evolves so that the volumesof differential volume elements are preserved.• In other words, the Jacobian determinant is 1.
• Emittance is the area of the projection of the beam’s phase-space volumeonto a particular (xi, Pi) plane.
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Expansion of Trajectories
Expand trajectory Y = T(X) in Taylor series about design orbit:
~Y = ~T0 +
6∑
i=1
∂~T
∂∆Xi
(0)Xi +
6∑
i,j=6
∂2~T
∂∆Xi∆Xj
(0)XjXk + . . .
Linear first order derivative is Jacobian matrix M of transformation with
Mij =∂Yi
∂Xj
=∂Ti
∂Xj
• Liouville’s theorem requires that |M| = 1.
• A more restrictive requirement is that M be symplectic: M ∈ Sp(2n,R)(e.g., see Goldstein’s Classical Mechanics, 2nd Ed.)
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Matrices for various elements
• In linear modeling we just calculate the Jacobian matrix for each individualelement (drift, dipole, quad).
• Then to propagate through a group of elements, we just need to multiplymatrices.
• Matrix for a drift of length `
Md =
1 ` 0 0 0 00 1 0 0 0 00 0 1 ` 0 00 0 0 1 0 00 0 0 0 1 00 0 0 0 0 1
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• For a horizontal bend, i.e., sector dipoleof design radius ρ and bend angle θ):
ρ
θ
Mb =
cos θ ρ sin θ 0 0 0 ρ(1 − cos θ)− 1
ρsin θ cos θ 0 0 0 sin θ0 0 1 ρθ 0 00 0 0 1 0 0
− sin θ −ρ(1 − cos θ) 0 0 0 −ρ(θ − sin θ)0 0 0 0 0 1
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• For a quadrupole of length ` and strength k = qp
∂By
∂x(k of Hill’s Eqn.):
• (This is a horizontally focusing quad if k > 0.)
Mqf =
cos(√k`) 1√
ksin(
√k`) 0 0 0 0
−√k sin(
√k`) cos(
√k`) 0 0 0 0
0 0 cosh(√k`) 1√
ksinh(
√k`) 0 0
0 0√k sinh(
√k`) cosh(
√k`) 0 0
0 0 0 0 1 00 0 0 0 0 1
• If k < 0, quad is horiz defocusing; replace upper-left 4×4 block with:
cosh(√
|k|`) 1√|k|
sinh(√
|k|`) 0 0√
|k| sinh(√
|k|`) cosh(√
|k|`) 0 0
0 0 cos(√
|k|`) 1√|k|
sin(√
|k|`)
0 0 −√
|k| sin(√
|k|`) cos(√
|k|`)
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• For a solenoid of length ` and field B• Define k = qB0
p
Msol =
1+cos kl2
sin klk
sin kl2
1−cos klk
0 0
−k sin kl4
1+cos kl2
−k 1−coskl4
sin kl2
0 0
− sin kl2
− 1−cosklk
1+cos kl2
sin klk
0 0
k 1−coskl4
− sin kl2
−k sin kl4
1+cos kl2
0 00 0 0 0 1 00 0 0 0 0 1
• Notice that this matrix couples the horiz. and vert. motion.
• For experiment solenoids at high energy, the coupling terms are generallysmall but nonnegligble.
limp→∞
Msol = Md.
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FODO: Trajectory and Envelope
Lattice with 10 FODO cells
-0.004
-0.003
-0.002
-0.001
0
0.001
0.002
0.003
0.004
0 20 40 60 80 100 120 140
y [m
]
s [m]
kf=0.32 kd=-0.31 (x,x’,y,y’,delta)_0=(0.001,0,0.001,0.0002,0.00) gamma=10.0
• Red curve is 1st turn.
• Blue curve is 2nd turn.
-0.004
-0.003
-0.002
-0.001
0
0.001
0.002
0.003
0.004
0 20 40 60 80 100 120 140y
[m]
s [m]
kf=0.32 kd=-0.31 (x,x’,y,y’,delta)_0=(0.001,0,0.001,0.0002,0.00) gamma=10.0
• 50 turns begin to fill up envelope.
• Envelope ∝√
β(s).
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RHIC beta functions
0
5
10
15
20
25
30
35
40
45
0 500 1000 1500 2000 2500 3000 3500 4000
√ β
[m1/
2 ]
s [m]
βxβy
0
5
10
15
20
25
30
35
40
45
400 500 600 700 800 900
√ β
[m1/
2 ]
s [m]
βxβy
• Polarized proton lattice at 100 GeV.
• Right plot is zoomed in around PHENIX.
• STAR and PHENIX: β∗ = 0.7 m; 7.5 m at other IR’s.
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• One turn matrix: M1turn =∏N
j=1 Mj
• Can get tunes from eigenvalues: λ±j = e±i2πQj
• Stable motion for real Qj ; unstable if Qj complex (not real).
• Can permute product of matrices to propagate the 1-turn matrix.• Tunes don’t depend on starting point, i.e. eigenvalues invariant under
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Dispersion Function
• Inhomogeneous solution Hill’s Equation:
x′′ + kx(s)x =δ
ρ(s)
η′′x + kx(s)ηx =δ
ρ(s)
• Dispersion function is periodic: ηx(s+ L) = ηx(s).
x(s) = xβ(s) + xδ(s)
= xβ(s) + ηx(s)δ with δ = ∆pp
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Dispersion of FODO Lattice
0
0.0005
0.001
0.0015
0.002
0.0025
0.003
0 20 40 60 80 100 120 140
x [m
]
s [m]
kf=0.315 kd=-0.30 (x,x’,y,y’,delta)_0=(0.00262,-0.000424,0.001,0.0002,0.001)
Vrf = 0
δ =∆p
p= 0.001
ηmax = 2.62 m
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Tunes for the simple FODO lattice
0.001
0.01
0.1
1
10
0 0.1 0.2 0.3 0.4 0.5
ampl
itude
fract H tune
0.0001
0.001
0.01
0.1
1
0 0.1 0.2 0.3 0.4 0.5
ampl
itude
fract V tune
qx = 0.2766, qy = 0.3301, Qs = 0.0153
• Single particle tracked for 2048 turns.
• With sextupoles to correct chromaticities (i.e. a nonlinearity).
• With coupling (rotate 1st quad by 0.007 radian).
• Strong synchrotron sidebands
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Chromaticity
ξx =dQx
dδ, ξy =
dQy
dδ
Recall Homogeneous Hill’s Eqn.: x′′ + k(s)x = 0
For a quadrupole:
k =q
p
∂By
∂x=
q
p0(1 + δ)
∂By
∂x' k0(1 − δ)
• Shifting the momentum changes the focusing of each quad.• Thus it shifts the tunes.
• Compensate with sextupole magnets: By = b2(x2 − y2), Bx = 2b2xy.
• x = xβ + ηxδ• Downside: introduces amplitude dependent tune shifts.
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RHIC tunes from Schottky cavity
• Can see coherent and incoherent tune information.
• Left shows high freq Schottky harmonics (∼2 GHz) with betatron sidebands.
• Right shows synchrotron sidebands around revolution harmonic.
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Transverse beam size
σ2x = 〈(x2 − 〈x〉2)〉 = 〈(x2
β + x2δ + 2xβxδ − 〈xβ〉2 − 〈xδ〉2 − 2〈xβ〉〈xδ〉)〉
= 〈x2β〉 − 〈xβ〉2 + 〈x2
δ〉 − 〈xδ〉2
= σ2xβ
+ σ2xδ
= βxεx,rms + η2xσ
2δ ,
since the betatron and synchrotron oscillations are independent and should beadded in quadrature.
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Transverse emittances
The rms contour ellipse in the xx′ phase space has area= πεx,rms with
εx,rms =1
π
∮
x′rms dx ' 1
π
∮
px,rms
p0
dx =1
πβγmcIx
with the invariant Ix =∮
px,rms
• Normalized emittance: πεNrms = πεrms × βγ
• The decrease of ε(∝ 1βγ
) with energy is referred to as adiabatic damping.
• For a 95% contour ellipse: ε95% ' 6εrms, assuming a 2d Gaussian dist.
σx =
√
βxεN,95%x
6βγ+ η2
x
(
σp
p
)2
.
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RHIC dispersion function
-1
-0.5
0
0.5
1
1.5
2
0 500 1000 1500 2000 2500 3000 3500 4000
Hor
izon
tal d
ispe
rsio
n η x
[m
]
s [m]
-1
-0.5
0
0.5
1
1.5
2
400 500 600 700 800 900
Hor
izon
tal d
ispe
rsio
n η x
[m
]
s [m]
• RHIC dispersion with STAR and PHENIX β∗ = 0.7 m
• Right: zoomed in around PHENIX.
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Resonances
Resonance conditions can occur when
NxQx +NyQy +NzQz = N, for Nx, Ny, Nz, N ∈ Z
The beam can blow up or be driven out of the ring by a resonance.
• Integer resonances are typically driven by imperfections in the lattice, espe-cially a misalignment.• An integer resonance has a linear growth in amplitude.
• Quadrupoles can drive the half-integer resonances.
• Sextupoles typically drive 13-integer resonances.
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RHIC tune plane
28 29Qx29
30
Qy
Order=7 Periodicity=1Orders: 1234567
• NxQx +NyQy = N
• Order: Nx +Ny
• slope> 0 tend to be stable
• slope≤ 0 are unstable
• RHIC tunes for present run:• Qx = 28.695, Qy = 29.685• indicated by black dot.
• Nonlinearities smear the dot.
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Beam-beam interaction
-1
-0.8
-0.6
-0.4
-0.2
0
0.2
0.4
0.6
0.8
1
-4 -3 -2 -1 0 1 2 3 4distance from beam center in sigma
Functional form of beam-beam force
(1-exp(-0.5*x**2))/x1/xx/2
exp(-0.5*x**2)
Gaussian beam shape
Shape of transverse force
ρ=N√2πσ`
exp
(
− y2
2σ2
)
Fy =NZ2e2(1 + v
c)
2πε0`σf(y
σ)
f(x)=1 − exp(−x2
2)
x∆Qbb
NIP
∼ r02
N
εN,95%
• Same sign: repulsive force,i.e., lowers tunes
• A test particle sees an almost linear gradient in the core of the beam.• The beam-beam force produces odd harmonics.• r0 is classical radius; N is number of particles in bunch.
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RHIC protons:r0 = 1.5 × 10−18 m
N = 1.3 × 1011
εN,95% = 20 × 10−6 m
NIP = 2
∆Qbb ' 0.01
Some e+ + e− colliders have achieved |∆Qbb| ∼ 0.04.
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Luminosity
Interaction rate:
dN
dt= σL =
∫
σ(~X2, ~X1)ρ2(~X2, t) |~v1 − ~v2| ρ1(~X1, t) d6X2 d
6X1,
= |~v1 − ~v2| f0Nb σ
∫
ρ2(~x− ~v2t) ρ2(~x− ~v1t) d3x dt
~vj is the velocity of a particle in the jth beam.σ is the total cross section, andρ1 and ρ2 are the density distributions of the two beams.Nb is the number of bunch crossings per turn.
Instantaneous luminosity: L0 ' NbfrevN1N2
4πσxσy
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IR beam envelope shape: hour glass effect
In a field free region the beta functions are parabolic:
βi(s) = β∗i +
s2
β∗i
, for i ∈ x, y
σ
σmin
=
√
1 +
(
s
β∗
)2
-8
-6
-4
-2
0
2
4
6
8
-3 -2 -1 0 1 2 3be
am s
ize
[σ-1
min
]s [m]
Plotted for β∗ = 0.5 m.
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Hour glass factor
0
0.1
0.2
0.3
0.4
0.5
0.6
0.7
0.8
0.9
1
0.5 1 1.5 2 2.5 3 3.5 4 4.5 5
Hou
r gl
ass
fact
or R
(β∗ /σ
z)
β∗/σz
L = L0R(β∗/σz)
For round beams withβ∗
1x = β∗1y = β∗
1x = β∗1y
ε1x = ε1y = ε1x = ε1y
R(ξ) =1√π
∫ ∞
−∞
e−t2
1 +(
tξ
)2dt =
√π ξ eξ2
[1 − erf(ξ)].
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Courtesy of Wolfram Fischer
2009: RHIC Polarized proton collisions at 250 GeV
Lpeak ' 0.85 × 1032 cm−2s−1 (Design Manual: 2 × 1032 cm−2s−1)
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Courtesy of Wolfram Fischer
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Suggested reading
• M. Conte and W. W. MacKay, An Introduction to the Physics of Particle
Accelerators, 2nd Ed., World Sci. (2008).
• S. Y. Lee, Accelerator Physics, 2nd Ed., World Sci. (2004).
• D. A. Edwards and M. J. Syphers, An Introduction to the Physics of High
Energy Accelerators, John Wiley (1992).
• E. J. N. Wilson, An Introduction to Particle Accelerators, Oxford (2001).
• Bryant and Johnsen, The Principles of Circular Accelerators and Storage
Rings, Cambridge (1993).
• H. Weidemann, Particle Accelerator Physics, 2nd Ed., Springer (2007).
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