Transcript Document

Update on Large Angle
Beamstrahlung detector for
SuperKEKB
J. Flanagan, K. Kanazawa, KEK
H. Farhat, R. Gillard, G. Bonvicini,
Wayne State University
Goal: to build a 1% monitor of
beam-beam interaction parameters
Admin. status
• 2 graduate students added
• Hosei Yosan $50,000
spent for first prototype
hardware
• WSU in-kind contribution
of $43,000 (graduate
students salary)
• Nichibei $5,000 (not spent
yet)
• NSF 2 proposals pending
What is beamstrahlung
• The radiation of the particles of one beam due to the bending force of
the EM field of the other beam
• Many similarities with SR but
• Also some substantial differences due to very short “magnet”
(L=z/2√2),very strong magnet (10T at KEKB). Short magnets
produce a much broader angular distribution
• Discrimination against machine backgrounds done MOSTLY by
angular collimation. At SuperKEKB, small leftover backgrounds to be
further subtracted through spectral analysis
• Beamstrahlung POLARIZATION at specific azimuthal points provides
unique information about the beam-beam geometry.
Some examples of Large Angle
BMST pattern recognition
¼ CESR Set-up principal scheme
 Transverse view
 Optic channel
 Mirrors
 PBS
 Chromatic
mirrors
 PMT
numeration
Set-up general view
• East side of CLEO
• Mirrors and optic port
~6m apart from I.P.
• Optic channel with
wide band mirrors
On the top of set-up
• Input optics
channel
• Radiation
profile
scanner
• Optics path
extension
volume
Main CESR results page
• Signal(x) strongly
correlated to I+I-2
• Signal strongly
polarized according to
ratios of vertical
sigmas
• Total rates consistent
with expectations at
10.3 mrad
DESIGN OF THE SuperKEKB
DETECTOR
• Numerous changes compared to CESR
device provide far better signal, signal
stability, control of systematics, detector
uniformity
• Current test bench aims at characterization
of detector spectral response to 0.3%, and
test bench measurement of angular
acceptance
Most important change: much stronger beams at
SuperKEKB. Comparison at =5mrad, =300-600nm,
0.5mrad2 acceptance)
Ratio
Qty
CESR-c
S.KEKB
Sx(Hz)
6E4
3E11(L),1E11(H 2-6E6
) (Prel.)
Sy(Hz)
6E4
6E10(L),2E10(H 0.3-1E6
) (Prel.)
Bx(Hz)(N/)
2E6 (est.)
2E5(L),1E5(H)
0.05-0.1
By(Hz)(N/)
2E6 (est.)
2E6(L),1E6(H)
0.5-1
B(from beam)
Very small
Very small
Beam pipe insert
• View port location at ±90
degrees minimizes
backgrounds, polarization
measurement errors, and
provides redundancy against
beam orbit errors
• To be located anywhere
between 5 and 10 mrad from
the beam direction at the IP
• Suggested mirror and
window sizes: 1.5X2mm2
and 1.7X1.7 mm2 (we could
go lower at 10 mrad)
Beam transport and optics box
• Light is transported to
optics boxes by means of
simple (and replaceable)
black-anodized pipes (2.5
cm ID) and mirrors
• Device consists of
achromatic telescope with
pinhole optics, pol.
Splitter, and two gratings
illuminating 4 PMT with
filters (total system
32PMTs)
• Many adjustment screws
throughout system
Current activities
Current activities (all measurements to
0.1% except absolute calibration of PMTs)
• Characterization of PMTs (nearly done)
• Spectral characterization of all optical
components (mirrors, windows?, splitter,
gratings, PMTs)
• Uniformity of all components
• Build plywood optics box, check optics,
achromaticity and focus
• Build and test optics box
Some results
Extra slides
CESR mirrors technical design
Check for alignment @ 4.2GeV
Directionality
• Scanning is routinely
done to reconfirm the
centroid of the
luminous spot.
If the angle can be considered
large and constant…
• Assuming (atan(z/)+atan((L-z)/ ) as the
field profile, one gets (u=s,c=cos,sin())
d P (1 uc)  (su) 1
2

exp(


/c)
2 6
2
dd (1 u ) 
2
2
2
Large angle beamstrahlung
power
• Total energy for perfect collision by beam 1 is:
P0=0.112re3mc2N1N22/(x2z)
• Wider angular distribution (compared to quadrupole SR)
provides main background separation
• CESR regime: exponent is about 4.5
• ILC regime: exponent is very small
• KEKB: exponent is small
3 z
   z
d I
1

P0 4 4 exp(
)
2
dd 4c   
16c
2
2 4
2
2nd major change: much better
event record
• CESR record contained BMST data, bunch-by-bunch
currents, luminosity monitors, independent measurements
of vertical heights, energy, as well as other unused
quantities. Beam length and beam horizontal size were
computed by measuring size of luminous region using
CLEO hadronic events.
• Need at least Beam Position Monitors near the IP to
monitor beam shifts both in quads and in detector-beam
axis angle
Properties of large angle radiation
•
•
It corresponds to the near backward
direction in electron rest frame (5
degrees at CESR, 2-4 degrees at
KEKB/SuperKEKB, 7 degrees at
DAPHNE)
Lorentz transformation of EM field
produces a 8-fold pattern,
unpolarized as whole, but locally
up to 100% polarized according to
cos2(2), sin2(2) with respect to
direction of bending force (Bassetti
et al., 1983)
Beam-beam interaction (BBI)
d.o.f. (gaussian approximation)