Transverse Impedance Localization in SPS Ring using HEADTAIL macroparticle simulations Candidato:...

Transverse Impedance Localization in SPS Ring

using HEADTAIL macroparticle simulations

Candidato:Nicolò Biancacci

Relatore:

Prof. L.Palumbo

Correlatore (Roma):Dr. M.Migliorati

Supervisore (CERN):Dr. B.Salvant

2/18

• CERN experiments and accelerator chain• SPS: lattice and beam parameters

• Impedance and wake fields in transverse plane

• Derived formulae for response matrix construction• Response matrix studies• Linearity and accuracy limits in the algorithm

Outlook

Introduction to CERN and CERN-SPS

Impedance and wake fields

Detection algorithm

CERN CERN European Organization for Nuclear Research (1954)

• Higgs Boson• Matter / Antimatter• String theory• Neutrino• CP violation• . . .

Research

3/18

CERN CERN European Organization for Nuclear Research (1954)

• Higgs Boson• Matter / Antimatter• String theory• Neutrino• CP violation• . . .

• Linac2 → 50MeV• PS-Booster → 1.4 GeV• PS → 25 GeV• SPS → 450 GeV• LHC → 7TeV

Accelerator chain

Research

4/18

CERN-SPS CERN-SPS Super Proton Synchrotron

• Energy: 25 GeV - 450 GeV

• Length: 6911.5038m

• Phase advance ∆Ф:

90⁰ or 180⁰ or 270⁰

• (βQD, βQF)≈(20m , 100m)

• (Qx, Qy) ≈ (26.13, 26.18)

L ATTICE parameters

QF QDx

y

sQF

BPM

)(s

∆Ф

))(cos()()( 0 sssy

Equation of particle motion

Focusing quadrupole

Defocusing quadrupole

Beam Position Monitor

Beta function

5/18

CERN-SPS CERN-SPS Super Proton Synchrotron

BEAM parameters

• Population Nb :

• Bunch length : 14 cm

• Transv. Emittance : 11 um

But…

Coupling Impedance is one of the main sources of instability. Need both global and local monitoring.

111015.1

S

yx,

y’(s)

S

s y(s)

Nbyx,

High intensity beams are needed to achieve high number of collision events in experiments.

Beams are subject to losses and degradation because of different instability sources

6/18

CERN-SPS CERN-SPS Impedance Impedance

ImpedanceWake fieldEM fieldsBeam current

v

Maxwell’s equations

Example of charged beam exciting e.m. fields passing by discontinuities. (courtesy of B.Salvant)

y2y1

s

Lq1q2

Dipolar wake and quadrupolar wake (V/mm pC)

‘’Angle kick’’

7/18


x

y

sBPV

SPS injection kickerMKPA.11936

8/18


BEAT0

x

y

s

BEAT0

• Impedance acts like a defocusing thin lens (in vertical plane). • This effect is also proportional to the number of particles in the beam.

)('

)(

1)(

01

)('

)(

1

1

2

2

sy

sy

Nksy

sy

by

SPS injection kickerMKPA.11936

Nb ∆y(s) ∆Ky

BPV

9/18


1. “Small” tune shift ( < 0.01)

2. Linear tune shift with Intensity3. Local impedances not coupled

4. Linear response with ∆k variation

Assumptions:

Local observable

Phase advance beating slope

Global observable

Tune shift slope

From linear optics:

10/18

We can measure:

with μ(s)=φ(s)/2π

Courtesy of H.Burkhardt, B.Salvant

Pseudoinverse

Tracking data

BPH BPV

N

*HDTL release developed by D.Quatraro and G.Rumolo.

CERN-SPS CERN-SPS Impedance Impedance Detection Algorithm Detection Algorithm

Fourier analysis

11/18

CERN-SPS CERN-SPS Impedance Impedance Response MatrixResponse MatrixDetection Algorithm Detection Algorithm

We can compute the response matrix using MAD-X or FORMULAE* we derived.

*Details in our thesis report.

Z Z Z s

BPV BPV

Response with formulae

Faster (few sec)

Easier add/remove lenses for reconstruction

No changes in lattice

Response with MAD-X

Slower (1.5h)

Non linear model

(a) (b) (c)

(a)

(b)

(c)

(a)

(b)

(c)

s1 s290 ⁰, 270 ⁰

180 ⁰

12/18

1

2

3

CERN-SPS CERN-SPS Impedance Impedance Response MatrixResponse MatrixDetection Algorithm Detection Algorithm

Past response matrix.

1. 180 ⁰ phase jumps.2. 270 ⁰ phase jumps and

duplication.3. Blank lines: more

reconstructors in same place and/or different response because of smaller beta function

New response matrix.

1. Smooth response normalizing on betatron function.

2. Lenses also in impedance positions (benchmark).

13/18

s

BPM pair

lenses

MKPA.11936 at 619 m

Lenses position (m)

Z

MKPA.11936 at 619 m

-1

For the most simple case of one single kick the algorithm presents peaks at the boundary.

Linearity and accuracy studies.

CERN-SPS CERN-SPS Impedance Impedance Response MatrixResponse MatrixDetection Algorithm Detection Algorithm Linearity & AccuracyLinearity & Accuracy

14/18

2 BPMs KickK

DFT TU

NE

NO

N LIN

EARITY CERN-SPS CERN-SPS Impedance Impedance Response MatrixResponse MatrixDetection Algorithm Detection Algorithm Linearity & AccuracyLinearity & Accuracy

15/18

DFT TU

NE

NO

N LIN

EARITY

MKPA.11936 MKP all MKPA.11936 x100

mMmMZ j /20,/2)Im(


16/18


DFT

TUN

E

• Increase Impedance• Beta bump

NO

N LIN

EARITY

• Increase N or SNR• Tune close to 0.5• Complex DFT

Z

17/18

Detection algorithm The algorithm was made fully working again. Main assumptions behind it were analyzed.

Response matrix Thin lens reconstruction was implemented. Analytical formulae derived to make reconstructing faster. Improved understanding between lattice and corresponding response matrix.

Linearity and accuracy

Main limits in DFT accuracy. • Increase accuracy with higher N of turns, complex DFT, higher SNR with larger beam displacement or tune close to half an integer.• Increase artificially the impedance to the detectable area.


18/18

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Transverse Impedance Localization in SPS Ring using HEADTAIL macroparticle simulations Candidato:...

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