durridge radon measurement technology present & future
TRANSCRIPT
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Dr. S. W. Sadler
NORM-IX, Denver, 24 September 2019
DURRIDGE Radon Measurement
Technology – Present & Future
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Contents
1. Comparison of current DURRIDGE
technology (RAD7) with Pulse Ionization
Chambers.
2. Future DURRIDGE technology –
Preliminary sensitivity measurements of
our next-generation prototype.
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Part 1
1. Comparison of current DURRIDGE
technology (RAD7) with Pulse Ionization
Chambers.
2. Future DURRIDGE technology –
Preliminary sensitivity measurements of
our next-generation prototype.
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Radon Overview
• Radioactive gas found in the environment.
• Collects in dwellings and workplaces under certain conditions.
• Inert, colorless, odorless – undetectable by the human body.
• Radon and its decay products emit ionizing radiation when they decay.
• 21,000 deaths per annum in the USAcaused by radon-related lung cancers.
CONFIDENTIAL 4
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Overview of Continuous Radon
Measurement Technologies
4 types:
1. Ionization Chambers
2. Scintillation Counters (Lucas Cells)
3. Pulse Ionization Chambers
4. Electrostatic Precipitation Instruments
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2 major drawbacks:
• 1) Background from 210Po increases over
the lifetime of the instrument.
• 2) No thoron / radon discrimination.
Pulse Ionization Chambers - Overview
• Ionization electrons created as
decay alphas are stopped in the air
inside the chamber. These form
negative ions with O2 molecules,
which then drift to the anode.
• Signal is the primary alpha decay of
radon + subsequent 218Po decay.
• Energy resolution of ~ 0.25 MeV
achievable for ~ 5 MeV alpha
decays.
• Large volumes and high collection
efficiencies are possible, leading to
sensitivities as high as 50
cpm/kBq/m3.
6
From https://www.bertin-instruments.com/wp-content/uploads/secured-file/ALGU_Manual_2012-08_E.pdf
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Example Pulse Ionization Chamber
Energy Spectrum
7
Co
un
ts
5.49 MeV
5.29 MeV
5.31 MeV
6.00 MeV
7.69 MeV
220 Rn
210 Po
• Changes in radon concentration are
seen near-instantly in the purple
peak.
• Energy peaks from radon, thoron
and 210Po background overlap in this
peak. No clear energy separation.
• Only partial separation of 218Po and 222Rn peaks.
212 Bi 6.05 MeV
Modified from http://www.gammadata.se/assets/Uploads/ATMOS-12-DPX-EN-ver1.51.pdf
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Electrostatic Precipitation Instrument – RAD7
• High-resolution alpha spectrometry of
radon decay products to determine
radon and thoron concentration and
reject backgrounds.
• Electrostatic collection of radon
daughters on a silicon detector, followed
by high-resolution alpha spectrometry.
• Simultaneous, independent
measurement of radon and thoron.
• Normal (Sniff) Mode Sensitivity:
13 (6.7) cpm/kBq/m3
• Intrinsic Background:
0.2 Bq/m3 for lifetime of the instrument.
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RAD7 Measurement Technology
Electrostatic precipitation with
Alpha Spectrometry
• Radon and thoron admitted, progeny blocked.
• Radon decays to charged 218Po.
• 218Po precipitated onto a silicon detector by
electric field.
• 218Po decays to 214Po, 50% chance to be
measured (due to geometry). Full energy seen
by silicon detector.
• 214Po decays, 50% chance to be measured.
Again, full energy seen.
• Radon concentration calculated by:
Sniff Mode: Rate of decay of 218Po in the A
Window.
Normal Mode: Rate of decay of 218Po + 214Po in
the A and C Windows RAD7 Measurement Chamber
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Inlet filter Silicon detector
HV ‘dome’Air pump
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RAD7 Alpha Energy Spectrum
• Near-perfect background rejection,
including long-lived 210Po
contamination (purple peak).
• Near-perfect Radon/Thoron
Discrimination (green/blue vs
red/orange peaks).
10
Co
un
ts
210Po 218Po 216Po 214Po 212Po
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Side-By-Side Spectrum Comparison
11
Example spectrum from a pulse ionisation type radon detector. Radon and thoron peaks overlap with each other, and with the 210 Po background peak. Low-energy shoulder from partially contained (mis-measured) events. Energy resolution of this model: 0.25 MeV.
5.49 MeV
5.29 MeV
5.31 MeV
6.00 MeV
7.69 MeV
Pulse Ionisation Chamber
Example RAD7 spectrum showing radon daughter and granddaughter peaks (218Po and 214Po), thoron daughter and granddaughter peaks (216Po and 212Po), plus rejected 210Po peak. All peaks show near-perfect energy separation, allowing near-perfect background rejection and simultaneous, independent measurement of radon and thoron.
Electrostatic Precipitation
Co
unts
210Po
218Po
216Po
214Po
212Po220 Rn
210 Po
212 Bi 6.05 MeV
Pulse ionization chamber spectrum image modified from http://www.gammadata.se/assets/Uploads/ATMOS-12-DPX-EN-ver1.51.pdf
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Part 2
1. Comparison of current DURRIDGE
technology (RAD7) with Pulse Ionization
Chambers.
2. Future DURRIDGE technology –
Preliminary sensitivity measurements of
our next-generation prototype.
12
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Next-Generation Prototype Spec.
• Same operating principle as the RAD7.
• Several improvements…
1. Waterproof and dustproof.
2. Large color touchscreen.
3. WiFi connectivity.
4. Faster electronics.
5. Higher-resolution digitizer.
6. Sensitivity the same as, or better than, the RAD7.
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Prototype – Sensitivity Measurement
• Sensitivity measured at DURRIDGE’s European calibration facility in Sheffield, UK.
• Constant radon concentration maintained in the radon reservoir tanks.
• 4 x RAD7 reference standards give the ‘true’ radon concentration.
• Simultaneous measurement with Prototype.
• Expose to radon for 24 x 2hrs. Discard first two data points to allow equilibration.
• Output: raw 12-bit spectrum of counts (4096 x 2.5 keV energy bins).
• Need to set the energy scale in order to calculate sensitivity…
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0 2 4 6 80
10
00
20
00
30
00
40
00
Energy (MeV)
AD
C I
nd
ex
Fit Data
R squared = 0.99999
p−value = 8.37e−09
Conversion factor = 401.96 +/− 0.63
Setting the Energy Scale
15
2000 2500 3000 3500 4000
01
00
200
30
04
00
50
0
ADC index
co
un
ts
218Po
216Po
214Po
212Po
• Find maxima of four alpha decay energy peaks.
• Plot the Analogue-to-Digital Converter (ADC) index against the known alpha decay energy.
• Straight line fit forced through the origin yields an extremely good fit, demonstrating a linear
energy response.
• Resulting conversion factor: 402.0 +/- 0.6 ADC points per MeV.
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Energy Windows
• Combine energy scale with RAD7 A, B, C, D window definitions (which we saw on slides 10 & 11) to yield energy windows for the prototype in ADC units:
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EnergyWindow Species LowerBound ADC index Upper bound ADC indexA 218 Po 2248 2569B 216 Po 2570 2890C 214 Po 2891 3291D 212 Po 3292 3733
• Sum counts in A window (Sniff mode) and A+C windows (Normal mode),
and divide by run time and radon concentration to yield sensitivity...
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Prototype – Preliminary Results
• Sniff (fast) mode sensitivity = 7.64 +/- 0.06 cpm/kBq/m3
• Normal (slow) mode sensitivity = 15.39 +/- 0.04 cpm/kBq/m3
• 15% higher than RAD7, which is the most sensitive electrostatic precipitation instrument on the market.
• Improvement achieved with a measurement chamber half the physical size of the RAD7’s.
• Lower than the leading pulse ionization chamber instrument, but with the benefit of radon/thoron discrimination and 210Po background rejection.
• Work is ongoing to improve on this sensitivity with further optimization of the dome geometry.
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Summary
• Pulse ionization chamber radon detectors have a fast initial response and high sensitivity.
• However, it is important to also consider two important drawbacks:
1. 210Po background build-up. Every radon decay you measure with such an instrument adds to the background, eventually making low-level measurements impossible.
2. No real-time radon/thoron discrimination.
• Both of these problems are solved by electrostatic precipitation instruments like the DURRIDGE RAD7, thanks to near-perfect separation of the various alpha decay energy peaks associated with the progeny of radon and thoron, and 210Pb.
• DURRIDGE’s prototype instrument has superior sensitivity to the RAD7 (currently the most sensitive electrostatic precipitation device on the market), as well as a host of other improvements.
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Thanks for listening!