Update on T2.4: Gd-lined plastic scintillator detector

1. Update on T2.4: Gd-lined plastic scintillator detector Raffaella De Vita INFN November 21st 2012

2. Outline • Detector Concept and Prototype Layout • Progresses since last SCINTILLA meeting • Tests of neutron capture medium and improvements of neutron capture efficiency • Development and implementation of new readout electronics and user interfaces • Data outputs and format • Preparation of DL2.4.2 • Detector layout for next technology benchmark • Future activity and time schedule SCINTILLA

3. Detector Concept and Prototype Layout 5” PMTs (20x40x80 cm3) • LAYOUT: • Plastic scintillator layers, wrapped in reflective foils and interlayered by Gd-coated foils • VME-based DAQ (commercial boards): • Total volume = 64 liters • Front surface = 3200 cm2 • OPERATION: • Detect presence of radioactive material via increase of pulse rates • Discriminate gammas and neutrons by different event topology: • - E>5 MeV • - Coincidence of Prompt-delayed events SCINTILLA

4. Neutron Absorber Test Setup • Validation of simulation results on Gd-oxide amount via measurement in dedicated test setup • Measurements of neutron capture time for different thickness of the scintillator and Gd-Oxide • Reduction of capture time by a factor 2.5 for an increase of absorber thickness of a factor 4 ➝ will be implemented for February technology benchmark • Reduction of capture time by a factor 1.5 for smaller scintillator thickness (1 cm vs. 2 cm) • ➝ will be implemented in final prototype 2cm-thick scintillator 1cm-thick scintillator SCINTILLA

5. DAQ Layout Hardware instrumentation Cables and connectionswith the detector Temperature monitoring embedded on the HV power supply boards SCINTILLA

6. The acquisitionprogramata glance… • At startup: • Checks the status of the hardware (enviromentalvariables) • Sets the HV channels to poweron the PMTs • Properlyinitializes the digitizerboard (thresholds, acquisition mode, integrationwindow, …) • Duringacquisition: • Monitors the rates of photon-like and neutron-likeevents • Notifiesneutron/photonalarmsifratesexceedthreshold • Writes data to output files (N42.42 and “expert” formats) • At the end of the acquisition: • Analyzes the data (energy and time distributions) • Shows summary plots on the Data Viewer SCINTILLA 6

7. First Tests Measurement of rates, spectra and prompt-delayedcoincidences with AmBe source SCINTILLA 7

8. N42.42 XML File structure The XML file is one of the output of our system. The planned XML file format has a structure divided into 3 parts: The HEADER: It describes the run taken. There is the list of parameters and definitions used for the analysis, followed by the environmental variables The CENTRAL PART: It contains all the data rates, counts and alarms recorded with acertain frequency The END of File: Summary of all the counts, mean rates AND all the alarms appeared along the run selected by radiation hypothesis (n and gamma) SCINTILLA 8

9. XML Header example (.xml file) <!– HEADER --> <?xml version="1.0" encoding="UTF-8"?> <?xml-model href="http://physics.nist.gov/N42/2011/N42/schematron/n42.sch" type="application/xml"?> <RadInstrumentData> <Remark> EXAMPLE XML FILE 2011 version </Remark> <Remark> ===== HEADER ===== </Remark> <Remark> Measurement Date: 003-11-22T23:45:00.6-07:00 and Location: Genova </Remark> <RadDetectorInformation id="RPM INFN-ANSALDO"> <RadInstrumentManufacturerName>INFN-ANSALDO</RadInstrumentManufacturerName> <RadInstrumentIdentifier> Aa1 </RadInstrumentIdentifier> <RadInstrumentModelName> Prototype 1 </RadInstrumentModelName> <!-- RadInstrumentDescription, RadInstrumentVersion --> <RadInstrumentClassCode>Portal Radiation Monitor</RadInstrumentClassCode> <RadInstrumentCharacteristics> <Characteristic> <CharacteristicName> Arm1 </CharacteristicName> <CharacteristicValue>40</CharacteristicValue> <CharacteristicValueUnits>centimeters</CharacteristicValueUnits> <CharacteristicValueDataClassCode>double</CharacteristicValueDataClassCode> </Characteristic> </RadInstrumentCharacteristics> </RadDetectorInformation> <RadDetectorInformation id="Aa1"> <!-- DNDO official name to be searched --> <RadDetectorName>Bar1 -Aa1-</RadDetectorName> <RadDetectorCategoryCode>Gamma-Neutron deiscriminator</RadDetectorCategoryCode> <RadDetectorKindCode>PVT</RadDetectorKindCode> <RadDetectorDescription> Comment about single bar </RadDetectorDescription> <RadDetectorLengthValue units="cm">40</RadDetectorLengthValue> <RadDetectorWidthValue units="cm">1</RadDetectorWidthValue> <RadDetectorDepthValue units="cm">10</RadDetectorDepthValue> </RadDetectorInformation> <EnergyWindows id="GammaWindowSettings”> <WindowStartEnergyValues>0 0 100</WindowStartEnergyValues> <WindowEndEnergyValues>100 3000 400</WindowEndEnergyValues> </EnergyWindows> <Remark> User: Operator </Remark>

10. XML Center and End of File example (.xml file) <!-- END of File --> <Remark> ==== END of File ==== </Remark> <AnalysisResults type="Arm1"> <AnalysisComputationDuration> PT2S </AnalysisComputationDuration> <GrossCountAnalysisResults id="Neutrons" radDetectorInformationReference="Bar1"> <TotalCountsValue> 3045 </TotalCountsValue> <AverageCountRateValue units="CPS"> 100 </AverageCountRateValue> <AverageCountRateUncertaintyValue units="CPS"> 0.1 </AverageCountRateUncertaintyValue> </GrossCountAnalysisResults> <GrossCountAnalysisResults type="Photons"> <TotalCountsValue> 3045 </TotalCountsValue> <AverageCountRateValue units="CPS"> 200 </AverageCountRateValue> <AverageCountRateUncertaintyValue units="CPS"> 1.2 </AverageCountRateUncertaintyValue> </GrossCountAnalysisResults> <RadAlarm id="Neutrons" radDetectorInformationReference="Bar1"> <RadAlarmDescription> Average rates alarms for Neutrons: 3 </RadAlarmDescription> </RadAlarm> <RadAlarmid="Photons" radDetectorInformationReference="Bar1"> <RadAlarmDescription> AverageratesalarmsforPhotons: 0 </RadAlarmDescription> </RadAlarm> <AnalysisResultDescription> PossibleState: Probable NORM. Alarm activeforphotonsradiations: NO. Alarm activeforneutronradiation: YES. Errormessages: NO. Detectorstatus: ACTIVE. </AnalysisResultDescription> </AnalysisResults> </RadInstrumentData> <!-- CENTRAL PART --> <Remark> ==== CENTRAL PART ==== </Remark> <!-- Per le environmental variables ci pensiamo poi --> <!-- Background --> <RadMeasurement> <MeasurementClassCode>Background</MeasurementClassCode> <StartDateTime> 003-11-22T23:45:00.6-07:00 </StartDateTime> <RealTimeDuration> PT100M </RealTimeDuration> <GrossCountsradDetectorInformationReference="Bar1" energyWindowsReference="GammaWindowSettings"> <CountData> 5 22 200 </CountData> <!-- With Gammawindows --> </GrossCounts> <GrossCountsradDetectorInformationReference="Bar2" > <CountData> 5 </CountData> <!-- Without Gammawindows --> </GrossCounts> </RadMeasurement> <!-- NEUTRONS --> <RadMeasurementGroup id="Neutrons"/> <!-- The same for Photons --> <RadMeasurement> <MeasurementClassCode> Measurement Run </MeasurementClassCode> <StartDateTime> 003-11-22T23:45:00.6-07:00 </StartDateTime> <RealTimeDuration> PT0.1S </RealTimeDuration> <GrossCountsradDetectorInformationReference="Bar1"> <CountData>5 22 200</CountData> </GrossCounts> <AverageCountRateValue> 12 </AverageCountRateValue> <AverageCountRateUncertaintyValue> 0.2 </AverageCountRateUncertaintyValue> </RadMeasurement> SCINTILLA 10

11. Preparation of DL2.4.2 • Deliverable 2.4.2: Technical Design of the Gd-Lined Plastic Scintillator Detector with Integrator Initial Guidelines for the Integration and Deployment of the Technology • Deadline: 31/12/2012 • Updated detector design: • Documentation of neutron capture studies➝ first draft available • Documentation of new electronic readout system ➝ first draft available • Documentation of updated detector layout ➝ in progress • Implementation of Integrator Guidelines: • Documentation of data output and N42.42 output format ➝ in progress • Other guidelines ➝to be started SCINTILLA 11

12. System Layout for Technology Benchmark • One pillar configuration • System size: • Detector: 60x30x195 cm3 • Electronic box: 60x15x40 cm3 • System console: 1 pc • Services: • Power line: 220 V, XXX W • One optical fiber from electronic box to system console (5 m, can be increased) • Ethernet line from system console to benchmarking server (?) source ELECTRONICS DETECTOR Optical Fiber to System Console direction of moving source 220 V SCINTILLA 12

13. Future Activity and Time Schedule • Work Plan: • Complete modifications of neutron absorber in the detector prototype • Complete the development of the new electronic readout and user interface • Complete he implementation of the N42.42 output format • Implement integration requirements for technology benchmark • Test new system with gamma and neutron sources in INFN lab SCINTILLA 13

14. backup SCINTILLA

15. XML example (web-browser) The final printed draft of the XML file is: EXAMPLE XML FILE 2011 version ===== HEADER ===== Measurement Date: 003-11-22T23:45:00.6-07:00 and Location: Genova INFN-ANSALDO Aa1 Prototype 1 Portal Radiation Monitor Arm1 40 centimeters double Bar1 -Aa1- Gamma-Neutron deiscriminator PVT Comment about single bar 40 1 10 0 0 100 100 3000 400 User: Operator ==== CENTRAL PART ==== Background 003-11-22T23:45:00.6-07:00 PT100M 5 22 200 5 Measurement Run 003-11-22T23:45:00.6-07:00 PT0.1S 5 22 200 12 0.2 ==== END of File ==== PT2S 3045 100 0.1 3045 200 1.2 Average rates alarms for Neutrons: 3 Average rates alarms for Photons: 0 Possible State: Probable NORM. Alarm active for photons radiations: NO. Alarm active for neutron radiation: YES. Error messages: NO. Detector status: ACTIVE. SCINTILLA 15

16. Readout and Data Processing Scheme SCINTILLA