1. Neutron Detection Techniques Geoff Gardner
Physics 556
Professor Koltick
2. Outline Neutrons Review
Common Reactions
Common Detectors
Commercial Detector Systems
Associated Hardware
Laboratory Techniques
“Secret Weapon”
3. Why detect Neutrons? Applications involving neutrons
Nuclear Power Plants
Scanning Technologies
Fundamental Physics
What does it mean to detect a neutron?
The detector needs to produce some sort of measurable signal
Electrical?
Audible?
4. Why is detecting Neutrons so Difficult Neutrons have mass but NO CHARGE!!!!
Can not directly produce ionization.
Can not be directly detected.
We must rely on some other mechanism or reaction to create the charged particle.
There are many varieties of charged particle detectors
5. Common Reactions 3He
n + 3He ? 3H + 1H + 0.764 MeV
BF3
n + 10B ? 7Li* + 4He (93%) ? 7Li + 4He + 0.48 MeV ? +2.3 MeV � ( 7%) ? 7Li + 4He + 2.8 MeV
Scintillation
n + 6Li ? 4He + 3H + 4.79 MeV
Cross sections only significant around thermal energies
6. Neutron Review Energy ranges
Thermal E ~ 0.025 eV
Epithermal E ~ 1 eV
Slow E ~ 1 keV
Fast E ~ 100 – 10MeV
Moderation of Neutrons
A decrease of intensity
“Slows” down or Decreases the Energy of the Neutron
At Thermal Energies
Capture Dominates (n,g)
Resonance Structure in Cross Section
Fast
Often occurs by inelastic scattering event (ballistic collision)
(n,p) (n,a), (n, 2n)
7. Neutron Elastic Scattering Events
8. Gas Proportional Counters
9. Scintillators Saint Gobain Crystals is a leading Manufacture
BC501 (data sheet)
BC720 (data sheet)
Properties of Scintillators
Efficiency (measured in percent) ~ Density
Photon Wavelength (measured in nm)
Photons per Neutron
Decay Time (good for liquids)
Materials
Li glass 7,000 photons/neutron
ZnS(Ag) 160,000 photons/neutron
Xylene ~ mineral oil
10. Semiconductor Detectors Thin Film coated semiconductors
Efficiency around 4%
Diodes with neutron reactive coating (B,Li)
Charged particles emitted, can attenuate in the film
Research on Enhancements (Kansas State)
Sandwiching layers of detectors
Doubled Films
Dimpled Surfaces
11. Detection Efficiency
12. Other Techniques
13. Texas Nuclear Neutron Dosimeter Moderator (10” polyethylene)
Scintillator (Li6I (Eu) crystal)
PMT (RCA 6199)
Preamplifier
Discriminator
Outputs (mrem/hr)
14. Canberra Dineutron
15. Laboratory Hardware Photomultiplier Tube (PMT)
Vacuum tube
Dynodes produce electron by “secondary emission”
Very High gain
mu mettal
Base (voltage divider)
Power Supplies (kV)
Discriminators
Constant Fraction Discriminator (CFD)
Time to Amplitude Converter (TAC)
Analog to Digital Converter (ADC)
Multi-Channel Analyzer (MCA)
Gate Generators
Counters & Scalars
16. Laboratory Techniques Pulse Shape Discrimination (PSD)
Characterize radiation event by pulse shape
17. Application
18. Neutron Flux Calibration Tool Testing two different scintillators
BC720 (hydrogenous plastic w/ ZnS phosphor)
BC501A (mineral oil)
Equipment Used
XP2230 (2” 12 stage LF)
Discriminator (lecroy 821)
Gate Generator (lecroy 222)
Visual Scaler (Joerger)
Fan outs, = signal path
Counts per 10/s
19. Application
20. References Radiation Detection and Measurement, Knoll
Introductory Nuclear Physics, Krane
High Efficiency Thin-Film Coated Semiconductor Neutron Detectors, D.S. McGregor, Kansas State University
Neutron Detectors for Materials Research, T.E. Mason, ORNL
www.saint-gobain.com
Kenny Wakeland, 2K Corporation
