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Dual-axis, Duo LateralPosition Sensitive Detectors
Robin Dienhoffer
State University of New York at Oswego
Advisor: Dr. Sherry Yennello
Cyclotron Institute, Texas A&M University
Outline
Particle Detectors Silicon Detectors Position Sensitive Detectors now New Position Sensitive Detector
Particle Detectors Materials and forms used
Solid, liquid & gasVarious elements
• Germanium, Cesium iodide, silicon, plastic… Various Attributes
Stopping power• ΔE vs. E plots
Energy and position resolutionCostEase of handling
Combining Detectors
Silicon Detectors
Not overly sensitive to humidity and operates well at room temperatures
Delicate, but not impossible to handle Still expensive, but becoming more
widely used Band Gap
Band Gap
Energy difference between valance band and conduction band Silicon is a good material to detect the
particles that we work with To get to the conduction band,
approximately 2.8 eV are needed To get a readable charge, electrons
must be excited enough to “jump” to the conduction band
This charge is then collected by the charge collection strips to be converted to signals
Valance Band
Conduction Band
Band Gap
What are PSDs?
PSD stands for Position Sensitive Detector
Collects deposited charge in such a way that the position of the particle can be determined
This will allow us a more thorough understanding of the underlying reaction mechanism that produced the charged particles
FAUST
The Forward Array Using Silicon Technology
Currently uses discrete detectorsPosition information
restricted to which detector was hit
Hoping to upgrade to PSDs, giving better position resolution
Some PSDs in Use
Pixilated DetectorsStrip detectors that use separated pads of
Silicon to detect where the particles hitThe number of channels of electronics limit
the feasibility of this option Resistive Detectors
Dual-axisTetra-lateralDADL
Dual-axis
Signal pulled from the edge centers
This results in circular pulling that must be adjusted through correcting algorithms
Dual-axis Tetra Lateral
Dual-axis Tetra lateral detector collects charge at all four of the corners on one face of the detector
This causes a pin-cushion effect which must, again, be accounted for using correction algorithm
Four Corner PSD – Dr. Tribble’s Group
Resistive sheet of Si on front and a non-resistive sheet on the back
resistive strips on front edges correct pincushion effect
Five signals- four on front and one on back (total energy)
Dual-axis, Duo Lateral
Dual-axis, duo lateral PSDs collect charge in a way which give position from both the front (horizontally) and the back (vertically). This method will lead to much less distortion than in previous models.
F1
F2
B1
B2
Guide wires for
charge
Front 1 Back 2
Front 2Back 1
Charge collecting strips
Detecting Location
Charge Collection
Guide Wires
L1 L2
L2L1
L2L1
Edge 1 Edge 2
When L1 = L2, both edges receive the equal charge, or Q1 = Q2When L1 > L2, Edge 1 receives less charge, or Q1 < Q2When L1 < L2, Edge 1 receives more charge, or Q1 > Q2
/\/\/\ /\/\/\ /\/\/\VoV1 V2
Vo = V1 + V2
Another Perspective
Settings
Found that biasing the front to 40.0 volts and the back guard ring to 5.0 volts is the most effective to get a clear energy spectra and position graph
Shaping time of 1 μs or 3 μs gives both good energy and position resolution
228Th Energy Spectra
5.432
5.686
6.051
6.288
6.778
8.784
228Th Position Graph
Beam Time: Ag + natAuΔE-E Graph
Z = 1
Z = 2
Z = 3 Proton
Deuteron
Triton
Beam Time: Ag + natAuPosition Graph
Hole Ratios
Mask Measured
3 mm 250 Chan.
2.5 mm 200 Chan.
1.5 mm 125 Chan.
Red = 1.20, 1.25 Green
Red = 0.50, 0.50Blue
Green = 1.67, 1.60 Blue
Future Use
This PSD design is currently being optimized for the future FAUST upgrade
Micron Semiconductor is offering this detector to the scientific community at large
Acknowledgements
Dr. Sherry Yennello SJY Group REU Program NSF, Grant _____ Robert A. Welch Foundation, Grant A-
1266 DOE, Grant DE-FG03-93ER40773.
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