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BIW’06 Glenn Decker
Development of a Hard X-ray Beam Position Monitor for
Insertion Device Beams at the APS
Glenn Decker1, Gerd Rosenbaum1,2, and Om Singh1
1Argonne National Laboratory, Argonne, IL 60439 USA2University of Georgia, Athens, GA 30602 USA
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BIW’06 Glenn Decker
• Advanced Photon Source Beam Stability Goals
• Present Level of Performance
• Hard X-ray Beam Position Monitor Design
• First Results, Future Plans
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BIW’06 Glenn Decker
Advanced Photon Source Beam Stability Goals
AC goals(based on 5% of present APS beam size, 0.017 Hz to 200Hz)
One week drift specification
Displacement (microns rms)
Angle(nanoradians rms)
Vertical 0.42 220
Horizontal 3.0 530
Displacement (microns p-p)
Angle(nanoradians p-p)
Vertical 1.0 500
Horizontal 5.0 1000
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BIW’06 Glenn Decker
ID’s
RFBPMs UV Photoemission BPMs
Existing Insertion Device and BPM Layout
e-
Detail of RF BPMPickup Electrode Geometry4 mm Diameter, rotated
Top View
P1 P2
e- -2.5 0 2.5 16.3 20 (meters)
γ
Distance from Source
End View
Vertical Aperture Size7.5 or 8 mm
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BIW’06 Glenn Decker
Insertion Device UltravioletPhoton Beam Position Monitor
Blade Geometries
A B
C D
Revised P2 Geometry(Installed at 5-ID, 7-ID, 14-ID)
μA
E
FμA
ABCD
ABEF
ABCD
μA
Insertion Device Gap (mm) Insertion Device Gap (mm)Insertion Device Gap (mm)
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BIW’06 Glenn Decker
Correction of Residual ID Photon BPM Gap-dependent Systematic Errors
ID 20 Gap (mm) ID 20 Gap (mm)
ID 20 Gap (mm) ID 20 Gap (mm)
Background Subtraction Only Background + Exponent Corrections
Δx / Σ(Absolute)
Δx / Σ(Relative)
100 microns
approx. 40 microns
Δx / Σ(Absolute)
Δx / Σ(Relative)
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BIW’06 Glenn Decker
Power Spectral Density Sqrt[Integ[PSD]] Sqrt[ReverseInteg[PSD]]
μrad2/Hz
μrad2/Hz
Horz.
Vert.
μradrms
μradrms
μradrms
μradrms
with Feedback
Frequency (Hz)
APS AC Pointing Stability, c.2005
without Feedback
Frequency (Hz)
Frequency (Hz) Frequency (Hz)Frequency (Hz)
Frequency (Hz)
220 nradGoal
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BIW’06 Glenn Decker
μrad
Pointing Angle Drift, One Week*
Local Steering
500 nradGoal
*Pointing Angles derived from UV photon bpms, fixed gap operation
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BIW’06 Glenn Decker
Beam-definingAperture
Water-cooledMoveable Scrapers
Shielded PIN Diode X-ray Detectors (4),Beryllium Filter
(Target: Cu or W)X-ray
Fluorescence
Plan View of Hard X-ray Beam Position Monitor Concept
White ID X-ray Beam
InsertableFilter Array(C)(Fixed)
Above and Below Plane of Beam
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BIW’06 Glenn Decker
Cooling Tubes
Horizontal Drive motor #1
Vertical Drive Motor
Horizontal Drive
Water-cooled mounting plates (Copper)
“Top View”
Motor #2 Spindle
Early Assembly of First Hard XBPM Prototype
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BIW’06 Glenn Decker
View along beam direction
Outboard Direction,away from the center of thestorage ring
Vertical direction, “Up”
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BIW’06 Glenn Decker
Data collected Jan. 30, 2006
Diode
Results of Diode Vertical Translation Stage Scan
CurrentμA
y (mm)By G. Rosenbaum APS Sector 19
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BIW’06 Glenn Decker
Δ / Σ
Translation stage position y (mm)
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BIW’06 Glenn Decker
Residual
Translation stage position y (mm)
μm
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BIW’06 Glenn Decker
Δ / Σ
Σ
Vertical Beam Position @ 52 meters (mm)
Result of Scanning BeamAcross Aperture with Local Angle Bump
ApertureDimension
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BIW’06 Glenn Decker
Summary / Future Plans
• Research is underway using the device at 52 meters from the source toward a photon bpm sensitive only to hard x-rays (> 9 keV) to achieve 500 nrad p-p pointing angle stability. Early results are very encouraging.
• Alternate detectors, including photoresistive single crystal CVD diamond (SLS development) and vibrating wires (Arutunian DIPAC ‘05) will be investigated.
• The effects of x-ray spectral shaping using photon filtering remain to be stud-ied.
• A second retractable high-power destructive diagnostic is being designed to be placed 25 meters from the source, downstream of the beam defining aperture.
• Ultimate goal is a non-destructive high-power device to be placed inside the accelerator enclosure, 20 meters from the source using existing UV bpm infra-structure.