A variation of the RadICAL (Radiation Imaging Cylinder Activity Locator) system capable of operating in a dynamic environment, such as that created by active interrogation techniques, has been developed. RadICAL is a novel method for locating a radiological source using a rotating detector element. The detector geometry is that of a thin sheet and is rotated to present a constantly changing surface area to the source; it therefore generates a characteristic temporal response which can be used to determine the source direction. The time required to determine the direction of a source make it unsuitable for dynamic environments and so an alternative method is presented that uses a stack of identical scintillator slabs positioned at fixed horizontal angles around a central axis. By comparing count rates from each slab to a standard response curve, using a specially developed algorithm, the direction of a source can be determined without the need to rotate the detector. EJ-299-33 plastic scintillator was used to allow detection of separate neutron and gamma events in a mixed field through pulse shape discrimination. A four element detector was built and shown to achieve a positional accuracy of approximately 4.4 degrees when exposed to a 1.44MBq 137 Cs source at distances of up to 2m. The same detector was used to discriminate separate neutron and gamma events in a mixed field, which allows for the possibility of locating a neutron source within a gamma rich environment

Duroe, K

Ellis, M

Jones, A

Joyce, M

Payne, C

Randall, G

Sellin, P

Speller, R

UCL Discovery

1RadICAL Stack: A localisation method for dynamicgamma/neutron fieldsGeorge Randall, Mark Ellis, Kirk Duroe, Ashley Jones, Malcolm Joyce, Chris Payne, Paul Sellin, Robert SpellerAbstract—A variation of the RadICAL (Radiation ImagingCylinder Activity Locator) system capable of operating in a dy-namic environment, such as that created by active interrogationtechniques, has been developed. RadICAL is a novel method forlocating a radiological source using a rotating detector element.The detector geometry is that of a thin sheet and is rotatedto present a constantly changing surface area to the source; ittherefore generates a characteristic temporal response which canbe used to determine the source direction. The time requiredto determine the direction of a source make it unsuitable fordynamic environments and so an alternative method is presentedthat uses a stack of identical scintillator slabs positioned atfixed horizontal angles around a central axis. By comparingcount rates from each slab to a standard response curve, usinga specially developed algorithm, the direction of a source canbe determined without the need to rotate the detector. EJ-299-33 plastic scintillator was used to allow detection of separateneutron and gamma events in a mixed field through pulse shapediscrimination. A four element detector was built and shown toachieve a positional accuracy of approximately 4.4 degrees whenexposed to a 1.44MBq 137Cs source at distances of up to 2m. Thesame detector was used to discriminate separate neutron andgamma events in a mixed field, which allows for the possibilityof locating a neutron source within a gamma rich environment.I. INTRODUCTIONTHIS document describes the development of a directional,neutron/gamma discriminating detection method that wasbuilt as part of a collaborative investigation that was under-taken between University College London, the University ofSurrey, Lancaster University and AWE to develop a detectionsystem for high flux, dynamic, mixed field active interrogationenvironments.A. The RadICAL ConceptRadICAL (Radiation Imaging Cylinder Activity Locator)uses a detection element whose general shape is that of a thinsheet. When the sheet is presented to the source face-on thearea of the detector is at its largest and the radiation pathlengthis minimum. When the sheet is turned so that only the edgeis presented the area is at its smallest and the pathlength ismaximum. Thus if the sheet is continually rotated, as shown inFigure 1, the solid angle subtended by the detector varies as itG.Randall and R.Speller are with the Department of Medical Physicsand Biomedical Engineering, University College London, UK e-mail:george.randall.10@ucl.ac.ukM.Ellis and K.Duroe are with AWE, Reading, UK.A.Jones and M.Joyce are with the Department of Engineering, Universityof Lancaster, UKC.Payne and P.Sellin are with the Department of Physics, University ofSurrey, UK.Manuscript received October 27, 2015; revised November 23, 2015.(a) A slab of scintillator rotates toproduce the RadICAL response (b) Geometry of scintillatorFig. 1: The RadICAL conceptFig. 2: Standard response of rotating detector exposed to singlepoint sourceis rotated in the radiation field and the fluctuating signal formsa characteristic response curve that can be used to locate thedirection of a source. The changing pathlength can counteractthis effect and alters the overall response shape slightly athigher energies. An example Standard Response Curve (SRC)is shown in Figure 2. The minimum count rates correspond tothe angle at which the small face of the scintillator is presentedto the source. This response has been tested extensively witha variety of different scintillation detectors, geometries andphoton sources and has been demonstrated to be an effectivemeans of locating a radioactive source without the use of acollimator [1]. The fraction of incident photons absorbed bythe rotating detector, at each angle, can be expressed as:NNo= e−∫µen(E).x(θ).dx (1)where: No = Total number of incident photons, N = numberof incident photons that pass through the detector withoutinteracting, µen(E) = attenuation coefficient at energy E andx = detector thickness at angle θ.2Fig. 3: An example of the dynamic fields observed in activeinterrogation environmentsB. Active InterrogationActive interrogation is a method of detecting specific mate-rials of interest by directing nuclear radiation, normally highenergy photons or neutrons, at a volume of interest. Whenbombarded by specific radiation various materials of interestmay undergo induced fission that will produce a uniquesignature in the form of prompt and delayed neutrons andgammas. A common application of this technique is in thedetection of special nuclear materials (SNM) such as highlyenriched uranium (235U) [2].An illustration of an active interrogation environment isshown in Figure 3 and demonstrates the dynamic signal andbackground intensities that follows an interrogation pulse.The separation time, ts represents the time, relative to theinitial interrogation pulse, after which the active signal canbe observed above the background.C. Neutron/Gamma Identification Using Pulse Shape Discrim-inationWhen using scintillation detectors to detect neutrons it isusually necessary to distinguish them from a larger gammafield. This is normally done by observing the different shapedpulses of electric current from the photodetector which corre-spond to neutrons or gammas interacting in the scintillator.In most scintillators nearly all of the light produced byscintillation is promptly emitted and can be described bya short decay time component. In some materials, notablyStilbene and various oxygen-free liquid scintillators, a size-able longer time component is also present. The compositeyield curve can often be described adequately by the sumof the two exponential decays, represented by each of thesecomponents [3]. The slow component is LET (linear energytransfer) dependent and so becomes pronounced by particleswith denser energy deposition tracks such as alpha particlesor recoil protons from fast neutron scattering [4].A new PVT based plastic scintillator, EJ-299-33, has beendeveloped by Eljen to deliver PSD in a similar manner toestablished liquid scintillators. This offers neutron detectionproperties without the handling problems associated withliquid organic scintillators. [5].A recent study, made as part of this collaboration, suggeststhat the quality of PSD in Eljen EJ-299-33 is shape dependent[6] and this might impose a limit on RadICAL performance.D. The RadICAL StackIn a dynamic field, such as those investigated during activeinterrogation, the time required to rotate between positionswith a conventional RadICAL detector would invalidate theconcept. A proposed variation on the RadICAL conceptprovides a potential solution to this problem and involvesreplacing the single rotating detector with a stack of identicalscintillators directly coupled to photodetectors and separatedat fixed angles around the centre of each slab of scintillator.The source position can be determined by fitting the individualcount rates from each of these detectors to a standard responsecurve using the least squares method.II. METHODSA. Building Four Element Stack DetectorA 4 element detector stack was built to be sensitive over a90◦ field of view. This involved 4 separate 150x35x12.5mmEljen EJ-299-33 scintillator slabs. The smallest face of eachslab was coupled directly to the window of an ET Enterprises9102B photomultiplier tube (PMT) and the remaining surfaceswere then covered in white, diffuse reflective, paint andwrapped in PTFE tape to minimise ambient light penetratingthe detector. Each detector was then mounted centrally withina separate, light tight, ABS enclosure. The four detectorelements were then stacked vertically and positioned at a 30◦offset to one another around an axis that corresponds withthe center of each scintillator slab. A diagram of this setup,including a detailed view of the top detector, is shown inFigure 4. Each PMT was then connected to a HV power supplyand a CAEN V1751 (10bit GSample/s) digitiser.B. Gamma Localisation ProcedureThe detector was initially tested by exposing to a 1.44MBq 137Cs source within the UCL laboratory. A set of fourCalibration Standard Response Curves (cSRC) was initiallytaken by rotating the complete detector stack around 270◦ ata distance of 1.55m from the source. These cSRC’s were thencompared to ensure that an identical shape could be observedfor each element. Minor differences were observed in the countrates due to an inconsistency in the efficiency of couplingeach element and PMT. This difference proved to be consistentbetween experiments and so these count rates were normalisedto produce a single cSRC.The stationary detector stack was then tested with the 137Cssource in 24 different positions, relative to the detector. Thesepositions covered a 60x100cm grid as shown in Figure 5 andin all positions the source was kept vertically aligned with thecentre of the detector. In each position separate acquisitionswere taken in windows of 10, 100 and 1000 seconds3Fig. 4: Plan of 4 element stack detector (all measurements arein mm)Fig. 5: Position of 137Cs source, relative to stationary detectorFor each source position and time window count rates forall four detectors were fit to the cSRC using the followingmethod:• Counts rates were multiplied by a scaling factor thatcorresponded to the counting efficiency of each detectorto allow them to be directly compared.• These four adjusted count rates were then scaled to fit thecount rate of the of the cSRC. This was done by using thedetector with the maximum detected counts to estimatethe maximum point on the curve and the max/min ratioof the cSRC to estimate the minimum point.• These scaled detector points were then fit to the cSRCusing a least squares method in order to find the directionof the source.C. Neutron/Gamma DiscriminationAn investigation was conducted to use the pulse shapediscrimination properties of the Eljen EJ-299-33 to identifyFig. 6: Normalised standard response of rotating detector andfitted pointsseparate gamma and neutron events within the detector. Thisinvolved exposing the detector to a 150 MBq 252Cf sourcewithin a low scatter environment at the National PhysicalLaboratories in Teddington, UK. The CAEN V1751 was usedwith its DPP-PSD software [7] to automatically calculate theratio of two charge integrals that correspond to a long and ashort gate for a single event. This value is know as the ’PSDnumber’ and can be plotted against the corresponding energyfor each event to discriminate gamma events from neutronsand other heavy particles. The detector was also exposed to a137Cs to produce an equivalent gamma only plot. Each set ofdata was then discriminated using the following method:• The 137Cs data was split between 400 different energybins.• The events in each of these bins were then placed in ahistogram according to their PSD value. For each set thisproduced an approximately Gaussian shape.• The PSD value that corresponds to the maximum of eachof these distributions and the FWHM were then loggedfor each energy bin.• This data was then used to determine a neutron/gammaseparation point.III. RESULTSA. Gamma Localisation ResultsResults for the procedure described in section IIB are shownin Table I. It was shown that the source could be localisedto within an average of 4.4◦ for 1000 second acquisitions,with the positional accuracy reducing as the acquisition timeis reduced. Each detector element registered between approxi-mately 35 and 75 events per second for this set of acquisitions.B. Neutron/Gamma Discrimination ResultsFigure 7 shows an energy-PSD plot for gamma only eventsfrom 137Cs. Figure 8 shows an equivalent plot for a mixedgamma and neutron field from 252Cf and depicts two distinctplumes that represent gamma and neutron events. Figure 8includes a 1 sigma neutron/gamma separation as described inthe method detailed in section IIC of this report. Both plotsshow a distinctive upwards curve in the PSD values as theenergy is increased. This is most likely due to high energypulses exceeding the maximum dynamic input range of thedigitiser. A significant overlap between neutron and gamma4Position MeasuredAngle (degrees)MeasuredDistance (mm) 10s 100s 1000sA1 0.0 155 10.6 9.4 8.4A2 6.7 145.3 16.1 0.1 1.9A3 14.2 137.8 22.6 1.6 2.6A4 22.4 132.9 4.8 23.2 3.8A5 31.1 130.9 48.5 5.5 8.5A6 39.8 132 0.2 1.8 2.2B1 4.3 174 5.3 11.7 7.7B2 10.3 164 14.3 4.7 0.3B3 17.1 158 0.5 0.5 6.5B4 24.1 153 13.5 5.5 5.5B5 31.9 152 2.7 8.3 6.7B6 39.0 152 17.4 0.6 2.4C1 6.8 191 15.8 2.8 3.8C2 12.6 183 4.0 1.0 2.0C3 18.9 177 3.7 7.3 2.3C4 25.1 173 16.5 5.5 6.5C5 32.0 172 8.4 8.6 7.6C6 38.6 172 2.5 1.0 0.0D1 9.4 210 28.2 2.2 0.2D2 14.0 202 6.4 3.4 1.6D3 20.3 196 0.7 22.3 2.7D4 26.0 193 14.6 7.4 13.6D5 32.3 191 11.7 8.7 7.3D6 38.4 192 16.8 3.2 1.2Mean Difference 11.9 6.1 4.4TABLE I: Gamma localisation results for 1.76 MBq 137Cssource exposed to detectorFig. 7: Energy-PSD plot for 137Csevents is apparent so a higher separation point is used tominimise falsely identified neutrons. By setting a 3 sigmaseparation for all detector elements just 0.3 percent of 137Csevents were positively identified as neutrons. These representa mixture of background neutrons and misidentified gammas.For the equivalent 252Cf plot 6 percent of events were identifiedas neutrons.IV. CONCLUSIONThe RadICAL Stack concept was demonstrated to be effec-tive and the curve fitting method can be seen to work as aneffective alternative to the previously demonstrated RadICALdetection method. Four stationary detector elements can beused to determine directional information about the positionof a source Positional accuracy has been demonstrated up to4.4◦ with a greater scope for improvement with higher fluxes.Pulse shape discrimination between neutron and gamma eventshas been demonstrated using the same detection elements usedfor imaging which allows the possibility of locating a neutronsource within a gamma rich environment. There is scope forFig. 8: Energy-PSD plot for 252Cf showing neutron/gammaseparation at 1 x sigmafurther work to be completed in providing separate neutronand gamma localisations within a mixed field.REFERENCES[1] G. Randall, E. Iglesis, H. F. Wong and R. Speller A method of provid-ing directionality for ionising radiation detectors–RadICAL Journal ofInstrumentation, 2014[2] D. R. Slaughter, M.R. Accatino, A. Bernstein, J.A. Church,M.A. Descalle, T.B. Gosnell, M. McDowell Preliminary results utilizinghigh-energy fission product gamma-rays to detect fissionable material incargo Nuclear Instruments and Methods in Physics Research, Section B:Beam Interactions with Materials and Atoms, 2005[3] G.F. Knoll Radiation Detection and Measurements, 3rd edition JohnWiley and Sons Inc., 2000[4] F.H. Attix Introduction to Radiological Physics and Radiation DosimetryJohn Wiley and Sons Inc., 1986[5] S. A. Pozzi, M.M. Bourne, S.D. Clarke Pulse shape discrimination inthe plastic scintillator EJ-299-33 Nuclear Instruments and Methods inPhysics Research, Section A: Accelerators, Spectrometers, Detectors andAssociated Equipment, 2013[6] C. Payne, P.J. Sellin, M. Ellis, K. Duroe, A. Jones, M. Joyce, G. Randall,R. Speller Neutron/gamma pulse shape discrimination in EJ-299 at highflux IEEE Nuclear Sciences Symposium, 2015[7] CAEN Digital Pulse Processing for Pulse Shape Discrimination UserManual UM2580, 2015c© British Crown Owned Copyright 2015/AWE

RadICAL stack: A localisation method for dynamic gamma/neutron fields

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RadICAL stack: A localisation method for dynamic gamma/neutron fields

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