DANE Status Report
C. Milardi, D. Alesini, M.E. Biagini, C. Biscari, R. Boni, M. Boscolo, B. Buonomo, A. Clozza, G. Delle Monache, E. Di Pasquale, G. Di Pirro, A. Drago, L. Falbo, A. Gallo, A. Ghigo, S. Guiducci, M. Incurvati, P. Iorio, C. Ligi, F. Marcellini, C. Marchetti, G. Mazzitelli, L. Pellegrino, M. Preger, L. Quintieri, P. Raimondi, R. Ricci, U. Rotundo, C. Sanelli, M. Serio, F. Sgamma, B. Spataro, A. Stecchi, A. Stella, S. Tommasini, C. Vaccarezza, M. Vescovi, M. Zobov
Scientific Committee 31 May - 1 Jun 2006
• KLOE run
• Machine studies
• DAFNE shutdown for FINUDA installation
Topics
KLOE off-energy run
Scan of the resonance:Ecm = 1023 MeVEcm = 1030 MeV > 10 pb-1 logged at each pointEcm = 1018 MeV (Nov 2005 ÷ Dec 2005) Ecm = 1010 MeV
Off-energy:Ecm = 1000 MeV 250 pb-1 logged (Jan 2006 ÷ Feb 2006)
Injection systemMagnetic elements scaled according to calibrations
Main Rings• Dipole and quadrupoles scaled according to calibrations• Wigglers constant since they work at maximum power supply current• Optics tuning to preserve the Twiss function @ IP, since the IR is based
on permanent magnet quadrupoles.
DANE off-energy configuration
Peak and daily integrated luminosity during the KLOE runs.
The maximum value of L∫day ~ 10 pb-1 has been obtained in Nov 2005.
The lower values during the 2006 runs correspond to off energy operation.
L∫day
DANE performance for KLOE :nbunches = 105 + 105 up to 111 + 111
I-total = 1.8 A
I+total = 1.3 ALpeak ~ 1.5x1032 cm-2 s-1 L∫day ~ 10 pb-1 (maximum value)L∫KLOE run = 2 fb-1 (May 2004 ÷ Nov 2005)
Lpeak
•LINAC faults (discharges in the klystron modulators, faults in the Uniform Field Solenoid PS)
•Water leakages in several elements (QUADs, RF, WGLs, SPLs)•Vacuum leakages in the e+ ring long sections•Faulty behaviour of the vacuum interlock in the e- RF cavity•Faults in the network connecting the front end processors of the Control System
•Sharing time with other activities (BTF and Synchrotron Radiation)
In the last three months DANE performance off-energy in terms of L∫ has been affected by :
DANE luminosity summary since 2001
The last points with lower L refer to the KLOE off-energy operation.
The Synchrotron Radiation laboratory and the Beam Test Facility (BTF) have been also operated in parasitic mode.
Few dedicated runs have been also delivered to the SR lab for special measurements and to the BTF.
Other activities
BTF experiment 2004/2005: AIRFLY, LCCal, AGILE-TRAKER, LNF-LHCb, CaPiRe, RAP, SIDDHARTA, FLAG, CRYSTAL, MEG, NANO, APACHE-LHCb, MCAL, LAZIO, BTeV, BTFLAB, BENCE, PASSRA, FISA, AIACE, ARGO, P326, GRALL, AGILE satellite, …
The AGILE Gamma Ray Imaging Detector calibration at BTF aimed at obtaining detailed data on all possible geometries and conditions. BTF provided data in the most significant energy region (20-700 MeV)
AGILE satellite in the BTF experimental hall
dedicated run 2 ÷ 20 Nov 2005≈30 % reduction in KLOE L∫
Machine studies (@ nominal E)(last two weeks in March)
•Study of background to KLOE during injection
•Test on the wires for Beam Beam Long Range interaction (BBLR) compensation
•Analysis of the KLOE background as a function of the scrapers position
•Test of the new transverse feedback in the e+ vertical plane
•Injection from the Linac switching off the chicane downstream the e+ converter
•Test on the new acquisition system for the single turn orbit measurements
•Test on the timing system to control the new power supply of the BTF pulsed magnet
•Bunch length measurements with an optics with a large negative c (~ -0.036)
•Optics measurements on the Transfer Lines
All machine studies were aimed at improving DANE performance for the next FINUDA run and at defining design criteria for an upgraded machine.
Optics application & tuningRF phase tuningCentral frequency 368.232 MHzResponse matrix acquisition & orbit correction
Bunch lenght measurement vs. I- at several values of VRF
fs = 38.3 KHz, VRF = 119 KV -> ac ~ - 0.036
e- ring optics c= -.036 (one day of machine study)
x model (line)
measured (points)
0
0,5
1
1,5
2
2,5
3
3,5
0 5 10 15 20 25
I [mA]
FWHM/2.35 [cm]
e-: 97 kV, -0.037
e- : 130 kV, +0.021
0
0,5
1
1,5
2
2,5
0 5 10 15 20 25
I [mA]
FWHM/2.35 [cm]
e+
e-
e- Lb versus stored current for:c = 0.02 red squaresc = - 0.036 blue dots
Lb versus stored current for:e+ c = 0.02 red squarese- c = - 0.036 blue dots
KLOE nominal optics c ~ 0.02
0,8
1
1,2
1,4
1,6
1,8
2
2,2
0 5 10 15 20
I [mA]
FWHM/2.35 [cm]
2 mA 7 mA
c = - 0.036VRF = 97 KV
c = - 0.021
VRF= 165 KV
Ith c3 / 2VRF
1/ 2
Microwave instability threshold Ith in the e- ring
Ith scales with c as expected
• Microwave instability threshold is reduced by a factor 3:
2 mA @ c = - 0.021
7 mA @ c = - 0.036
• With the same instability threshold the electron bunch length in the lattice with c = - 0.036 is ≈ 50% shorter than in the nominal conditions (c = + 0.02)
• The electron bunch is shorter than the positron one with nominal c
What have we learned from the shifts with c ~ -0.036 ?
In the DANE IRs the beams experience 24 Beam Beam Long Range interactions (parasitic crossing) limiting the maximum storable current.
Numerical simulations show that BBLR interaction can be compensated by current-carrying windings.
Wires for BBLR compensation
compensation wiresncoils = 20y
I
I
L = .215 m
z
L = .18 m
Wires installed in the KLOE Interaction Region (Nov 2005)
(G. Sensolini, R. Zarlenga)
Z = 4.887 m
IP1compensation winding
KLOE half IR simplified top view
Splitter
x
0
2000
4000
6000
8000
1 104
1.2 104
2.5 104 2.6 104 2.7 104 2.8 104 2.9 104 3 104
KLOE_20060322_fast
L [1
02
8 c
m-2
s-1]
Time [s]
0
200
400
600
800
1000
1200
1400
1600
2.5 104 2.6 104 2.7 104 2.8 104 2.9 104 3 104
KLOE_20060322_fast
I- [mA]
I+ [mA]
I- [mA
]
Time [s]
0
1000
2000
3000
4000
5000
6000
2.5 104 2.6 104 2.7 104 2.8 104 2.9 104 3 104
KLOE_20060322_fast
- [s]
+ [s]
- [s]
Time [s]
0
1000
2000
3000
4000
5000
6000
3000 4000 5000 6000 7000 8000
KLOE_20060322_fast
- [s]
+ [s]
- [s]
A
0
200
400
600
800
1000
1200
1400
1600
3000 4000 5000 6000 7000 8000
KLOE_20060322_fast
I- [mA]I+ [mA]
I [m
A]
Time [s]
0
2000
4000
6000
8000
1 104
1.2 104
3000 4000 5000 6000 7000 8000
KLOE_20060322_fast
L [
102
8 c
m-2
s-1]
Time [s]
WIRES
ON
WIRES
OFF
L I
400
500
600
700
800
900
1000
1100
0
2000
4000
6000
8000
1 104
-500 0 500 1000 1500 2000 2500 3000 3500
KLOE_21_22Mar06_merge 3:14:09 PM 24/5/06
I+ wires On
I+ [mA] wires OFF
+ wires ON
- wires OFF
I+ [
mA
] +
t [s]
higher lifetime +
beam lifetime independent from the other beam currentless beam-beam blow upDue to the higher + is possible to have the same L with less injections
What have we learned from the shifts with WIRES ?
DAFNE shutdown on March 31st
• Maintenance
• KLOE roll-out
• Upgrades
• FINUDA roll-in
Maintenance
• Plants:ElectricCoolingCryogenic
• Linac• Fuid system• Control System• Magnet power supplies• RF system• Vacuum system• Wigglers
Upgrades
Wiggler cooling system upgrade 8 Wigglers~ 150 spigots each wiggler
Simplified IR1 for FINUDA run
•IP1 • KLOE detector removed
• 4 electromagnetic QUADs • Compensator solenoids off
in order to have:• a flexible lattice• release the low beta configuration @ IP1• have a more efficient beam separation in IR1• have the same * @ IP2 as for KLOE
y = 0.018 m
x = 1.6 m
IR1 for FINUDA run
KLOE roll-out
removed
disconnected
moving
Ion-Clearing-Electrodes
Remove broken Ion-Clearing-Electrodes in the e- ring
Remove ICEs in the e- ring wigglers to reduce ring coupling impedance
In order to:
•Increase - geometric Luminosity - dynamics Luminosity
•Reduce - beam blow up above the microwave instability threshold - impact of quadrupole instability in the e- ring
MOTIVATION:
• Impedance of the DAFNE Main Rings:
• Impedance affects bunch length:
z- ≈ 2.7cm
z+ ≈ 2 cm measured @ Ib ~ 15 mA
e+
e-
mainly due to ICE in WGLs
Remove Ion Clearing Electrodes in e- Wigglers
3/13/1
6/12
o
z
n
Z
R
cRFs
c
hV
I
eE
I
cos
2
/2
Z
n
0
0.54
Z
n
0
1
e- Vertical Size Blow f(VRF, Ib)
10
15
20
25
30
35
0 10 20 30 40
I [mA]
e+ ring
e- ring
Bunch Length [mm]
~ 30%
0,15
0,2
0,25
0,3
0,35
0,4
50 100 150 200 250 300
1.5 mA9 mA19 mA
V [kV]
y [mm]
~ 66%
• Impedance affects vertical beam size as well
0,15
0,2
0,25
0,3
0,35
0,4
0 5 10 15 20 25 30
Ib[mA]
y [mm]
e- Vertical Size Blow Up
1,5
2
2,5
3
3,5
4
0 5 10 15 20 25 30
Ib[mA]
FWHM/2.3548 [cm]
- Single bunch (beam) effect
- It is correlated with the longitudinal microwave instability:
a) The same threshold
b) The same dependence on RF voltage
c) The threshold is higher for higher momentum compaction
d) More relevant for e- ring having higher coupling impedance
c = 0.02
c = 0.02
c = 0.034
c = 0.034
Vertical size
Bunch length
Conditions z (e-), cm z (e+), cm Gain, %
Normal operation
3.0 (meas.) 2.1 (meas.)
Low Impedance 2.3 2.1 18
A factor 2 reduction in e- ring impedence gives a GEOMETRIC LUMINOSITY GAIN
z 2
z 2
If x,y scale as
DAFNE Arc Chamber – Remote Tooling
Multipurpose remotized positioning system
y
x
About ICE removal
DAFNE Arc Chamber – Remote Tooling
Milling machine to cut ICE fingers
to extract them as a whole
finger
20 mm120 mm
Pneumatic piston Suction cupICE
Extractor fan
ICE break and removal ( backup solution)
Vacuum chamber cleaning
Wires for BBLR compensation in the IR2
Windings OFF Windings ON Windings ON(wrong polarity)
Particle equilibrium density in the transverse space of normalized betatron amplitude
Numerical simulations show that BBLR interactions can be compensated by current-carrying windings
Ay/ y
Ax/x
Ay/ y
Ay/ y
Ax/x Ax/x
New feedback board
Under test at SLAC,
KEK and LNF
Feedback upgrade III generation digital bunch-by-bunch feedback designed for
SuperB factory (collaboration SLAC-KEK-LNF)
- Features:- extremely compact- gain & phase digital and remote control- possibility to manage any betatron or synchrotron tunes - less sensitive to large oscillations at injection- real time parameter monitoring- powerful beam diagnostics- main DSP loop based on FPGA (Field Programmable Gate Array)
Power supplyHard disk unit PersonalComputer
Fan
Feedback test board
30cm
New Beam Position Monitors
5 complete stations will be installed on each ring for:
• single turn position measurements
• linear and nonlinear optics measurements( x,y x,y c11)
TiN coating
First test on a short straight section of the e+ ring in order to measure the e-cloud by using an e-cloud detector keeping as a reference the data coming from a symmetric section without coating.
2 e-cloud detectors will be installed in the e- ring
Control System
• Upgrade of the CS servers
• Gradual implementation of new front-end processors (Pentium/Linux)
• Extension of the CS Ethernet network in the LINAC area, BTF experimental hall, Damping Ring area, DAFNE hall
• Control software implementation for the new elements
New Injection Kickers
Expected benefits:•higher maximum stored currents•Improved stability of colliding beams during injection• less background allowing acquisition on during injection ? (it was off during FINUDA last run)
(D. Alesini and F. Marcellini)
New injection kickers with 5.4 ns pulse length have been designed to reduce the perturbation on the stored beam during injection
present pulse length ~150ns(old kickers)
t t
VT VT
FWHM pulse length ~5.4 ns
50 bunches 3 bunches
spectrometer
silicon tagging target
silicon detector
•high intensity beam (103-1010 particles)•Installation of a pulsed power supply to improve the duty cycle from 40% to 80% (June 2006)
•Installation of the Photon Tagged Source
BTF upgrades
BTF photon tagged source
experimental hall
Maintenance activities on schedule
KLOE roll-out completed
Finuda straight section removed, IR2 ready for FINUDA roll-in
All wigglers removed, hydraulic and electric maintenance almost completed, 2 magnets re-installed and aligned
Tests for ICE removal completed and removal scheduled for next week
Present status
Aug 7th ÷ Aug 28th summer shutdown
DANE startup ts depends on the FINUDA roll-in tr
ts = tr + (~13 days)
Thanks to the DANE Technical Staff !!
G. Baldini, P. Baldini, A. Battisti, A. Beatrici, M. Belli, B. Bolli, A. Camiletti, G. Ceccarelli, R. Ceccarelli, A. Cecchinelli, S. Ceravolo, R. Clementi, O. Coiro, S. De Biase, M. De Giorgi, N. De Sanctis, R. Di Raddo, M. Di Virgilio, G. Ermini, G. Fontana, U. Frasacco, C. Fusco, F. Galletti, M. Giabbai, O. Giacinti, E. Grossi, F. Iungo, R. Lanzi, V. Lollo, V. Luppino, M. Marchetti, C. Marini, M. Martinelli, A. Mazzenga, C. Mencarelli, M. Monteduro, A. Palleschi, M. Paris, E. Passarelli, V. Pavan, S. Pella, D. Pellegrini, R. Pieri, G. Piermarini, G. Possanza, S. Quaglia, F. Ronci, M. Rondinelli, F. Rubeo, M. Sardone, M. Scampati, G. Sensolini, R. Sorchetti, A. Sorgi, M. Sperati, A. Sprecacenere, P. Tiseo, R. Tonus, T. Tranquilli, M. Troiani, V. Valtriani, R. Zarlenga, A. Zolla.
…. for their commitment during DANE operation and shutdown
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