Measurement of Airborne Radioactivity by the CTBTO
Transcript of Measurement of Airborne Radioactivity by the CTBTO
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Measurement of Airborne Radioactivity by the CTBTO
Simon Jerome, NPL
ARMUG, 9th November 2004
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What is the CTBTO?
• The Comprehensive Test Ban Treaty Organisation
• An international organization established by the States Signatories to the Comprehensive Test Ban Treaty on 19th November 1996
• Their main task is the establishment of the 337 facility International Monitoring System and the International Data Centre, and the development of operational manuals, including for on-site inspections.
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Aims of the CTBTO
• To detect, locate and identify nuclear weapons tests down to 1kTequivalent
• The data used to detect, locate and analyse events are processedimmediately, with the first automated products being released within two hours
• The data comprise lists of seismoacoustic events and radionuclides that have been detected by monitoring stations
• Analysts subsequently review these lists in order to prepare quality controlled bulletins
• Implications of getting it wrong are not good
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Monitoring Technologies
• The aim – what, where, when, how, who (but not why)• Seismological monitoring system – size, location and time of underground
tests• Hydroacoustic monitoring detects acoustic waves – size, location and
time of underwater tests• Infrasound network detects very low-frequency sound waves in the
atmosphere – size, location and time of atmospheric tests• Radionuclide network of 80 stations uses air samplers to detect
radioactive particles released from atmospheric explosions and vented from underground or under water explosions (the ‘smoking gun’).
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Network Locations
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Nuclear Weapon
• Initial fission reaction (20 kT - 239Pu)• Fuels second fission reaction (<500 kt 239Pu or 235U)• second fission reaction fuels fusion reaction (yield depends how much fuel
2H/3H in the form Li2H)• finally, fast neutrons induce addition fissions in the weapon containment
(yield depends on rest of weapon – 238U)• Fission products elements from Zinc to Terbium, all volatalised
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Fission Products
Thermal Fission yield s
0.001
1.001
2.001
3.001
4.001
5.001
6.001
7.001
8.001
9.001
65 70 7 5 8 0 85 9 0 9 5 10 0 1 05 1 1 0 1 1 5 1 20 1 25 13 0 13 5 14 0 1 4 5 1 5 0 15 5 1 60 1 6 5 1 7 0
Mass number
% ma
ss yie
ld
Pu -239U-235Pu-241
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Radioactivity remaining
Rad ioactivity after 10 days
1.00E+00
2.00E+15
4.00E+15
6.00E+15
8.00E+15
1.00E+16
1.20E+16
1.40E+16
65 70 75 80 85 90 95 100 105 110 115 120 125 130 135 140 145 150 155 160 165 170
Mass number
Activ
ity/B
q
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Radionuclide monitoring
• The radionuclide network of 80 stations uses air samplers to detect radioactive particles released from atmospheric explosions and vented from underground/underwater explosions
• Half of the stations in the radionuclide network also have the capacity to detect noble gases
• The relative abundance of different radionuclides in these samples can distinguish between materials produced by a nuclear reactor and a nuclear explosion
• The associated radionuclide laboratories are used to analyse samples that are suspected of containing radionuclide materials that may have been produced by a nuclear explosion
• The presence of specific radionuclides provides unambiguous evidence of a nuclear explosion
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Performance requirements
• For the network of radionuclide stations:90% probability of detection within 14 days of any event >1 kT
• Distinguish between nuclear explosion and:Radon (allow the sample to decay)Radioactive Xenon used in nuclear medicineEmissions from civil nuclear facilitiesCosmogenic radionuclides
• Based on the detection of 140Ba with a detection limit of 10 µBq/m3
• 1 kT = ~4×1012J = 1.3×1023 fissions = 5 PBq 140Ba• Trying to detect not very much at all of the device!
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Radionuclide monitoring stations
• Air flow: 500 m3/hour• Collection time: 24 hours• Decay time: ≤24 hours• Measurement time: ≥20 hours• Reporting time: ≤72 hours• Reporting frequency: Daily• Collection efficiency: ≥80% for 0.2 µm and ≥60% for 10 µm• Measurement: High resolution γ spectrometry, 88-1836 keV• Sensitivity: εγ >40% leading to 10-30 µBq/m3 for 140Ba• Data availability: ≥95%• Down time: ≤7 days in a row, ≤15 days per year
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Xenon monitoring stations
• Air flow: 0.4 m3/hour• Sample volume: 10 m3
• Collection time: ≤24 hours• Measurement time: ≤24 hours• Reporting time: ≤48 hours• Reporting frequency: Daily• Nuclides monitored: 131mXe, 133Xe, 133mXe and 135Xe• Measurement: β–γ coincidence counting or high resolution γ
spectrometry• Sensitivity: 1 mBq/m3 for 133Xe• Data availability: ≥95%• Down time: ≤7 days in a row, ≤15 days per year
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Supporting measurement
• Network of 16 radionuclide laboratories around the world• Provide more detailed analysis of filters if required
Key Nuclides:95Zr/95Nb – timing99Mo – timing106Ru – fuel132Te/132I – event 140Ba/140La – timing141Ce/144Ce – fuelPure α and β emitting fuel and casing activation products
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CTBTO Country Profile for the UK
Coordinates Location Type Treaty
Code Lat Lon
Eskdalemuir EKA Auxiliary Seismic Station AS104 55.3 -3.2
BIOT/Chagos Archipelago Hydroacoustic Station HA08 -7.3 72.4 Tristan da Cunha Hydroacoustic Station HA09 -37.2 -12.5 Tristan da Cunha Infrasound Station IS49 -37.0 -12.3 Ascension Infrasound Station IS50 -8.0 -14.3 Bermuda Infrasound Station IS51 32.0 -64.5 BIOT/Chagos Archipelago Infrasound Station IS52 -5.0 72.0
AWE Blacknest Chilton Radionuclide Laboratory RL15 TBD TBD
BIOT/Chagos Archipelago Radionuclide Station RN66 -7.0 72.0 St. Helena Radionuclide Station RN67 -16.0 -6.0 Tristan da Cunha Radionuclide Station RN68 -37.0 -12.3 Halley, Antarctica Radionuclide Station RN69 -76.0 -28.0
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Noble gas sampling
• Xenon is adsorbed on charcoal, purified and concentrated• Need to remove water and CO2
Interfere with adsorption of Xenon on charcoal• Radon needs to be removed
Variable concentrations, but much larger than radioactive XenonGas chromatography is used to separate Radon and Xenon
• Variable backgroundNuclear medicine (mainly 133Xe)Nuclear power
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Noble gas measurement
• 131mXe, 133Xe, 133mXe and 135Xe emit γ–rays and similar energy X–ray• Can use γ spectrometry to detect 133Xe (81 keV, 37%), 133mXe (233 keV,
10%) and 135Xe (250 keV, 90%)• 131mXe emits 30 keV X-rays, but no γ–rays; 133Xe, 133mXe and 135Xe also
emit X–rays at this energy• Use β–γ coincidence counting techniques to reduce background for 133Xe
and 135Xe• Use γ–β coincidence counting (gated on 30 keV X–ray) with an energy
resolving β detector to reduce background for 131mXe and 133mXe
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Noble gas interferences
• 131mXe, 133Xe, 133mXe and 135Xe can be present at ground level with activities of up to 100 mBq/m3 from nuclear power and from medical use
• Typically 3-10 mBq/m3 in the industrialiased regions of the northern hemisphere
• (133mXe:133Xe)reactor ~0.1 (133mXe:133Xe)weapon ~10• (135Xe:133Xe) reactor ~0.01 (135Xe:133Xe)weapon ~100
• Medically used 133Xe is practically pure• Activity ratios are more important than activity concentrations in this case:
(131mXe:133Xe:133mXe:135Xe)weapon ~ 1:104:105:107
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Particulate sampling
• Particulate activity is captured on organically based band filters of differing types
• Filter exposed for 24 hours• Allowed to decay for 24 hours
Radon daughter nuclides (mainly 212Pb) decay over this period, reducing interference with 140BaAll other major radon daughters decay to zero in 24 hours
• Measured for 24 hours• Data reported to IDC in Vienna
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Fission Products
Thermal Fission yield s
0.001
1.001
2.001
3.001
4.001
5.001
6.001
7.001
8.001
9.001
65 70 7 5 8 0 85 9 0 9 5 10 0 1 05 1 1 0 1 1 5 1 20 1 25 13 0 13 5 14 0 1 4 5 1 5 0 15 5 1 60 1 6 5 1 7 0
Mass number
% ma
ss yie
ld
Pu -239U-235Pu-241
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Particulate measurement
• Need for calibration standards• Filter standards prepared from solution standards• Detectors calibrated directly (88-1836) keV• Monte Carlo and other modelling techniques not used• Comparison exercises to verify quality of information supplied• CTBTO has very similar quality requirements to ISO 17025
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Comparison exercises
• 2000:22Na, 124Sb, 125Sb, 134Cs, 137Cs, 154Eu, 155Eu, 210PbActivity levels 5 – 250 Bq/filter
• 2001:91Y, 95Zr/95Nb, 99Mo, 99mTc, 103Ru , 106Ru, 132Te/132I, 137Cs, 140Ba/140La, 141Ce, 144Ce, 147NdActivity levels 5–75 Bq/filter
• 2002:91Y, 95Zr/95Nb, 99Mo, 99mTc, 103Ru , 106Ru, 127Sb, 132Te/132I, 137Cs, 140Ba/140La, 141Ce, 147Nd, 154Eu, 155EuActivity levels 0.1–10 Bq/filter