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Passive detectors (nuclear track detectors) – part 2: Applications for neutrons This research project has been supported by the Marie Curie Initial Training.

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Presentation on theme: "Passive detectors (nuclear track detectors) – part 2: Applications for neutrons This research project has been supported by the Marie Curie Initial Training."— Presentation transcript:

1 Passive detectors (nuclear track detectors) – part 2: Applications for neutrons This research project has been supported by the Marie Curie Initial Training Network Fellowship of the European Community’s Seventh Framework Programme under Grant Agreement PITN-GA-4 2011-289198-ARDENT By: Alvin SASHALA NAIK Date: 25/03/2015 4th ARDENT Workshop: CTU, Prague, Czech Rep.

2 Outline 2  Overview of Neutron Physics in CR-39 detectors  Concept of Dose calculations from LET nc (mean LET) spectra  Neutron dosimetry: State of the art & the innovative approach  Other applications for neutrons spectrometry  Conclusion

3 Overview of Neutron Physics 3 Our applications of the CR-39 as dosimeter Ref: Principles of Radiation Interaction, 22.101, fall 2006, MIT open courseware

4 Energy Deposition by Neutrons: Neutrons are generated over a wide range of energies by a variety of different processes Like photons, neutrons are uncharged and do not interact with orbital electrons Neutrons can travel considerable distances through matter without interacting Neutrons will interact with atomic nuclei through several mechanisms:  Elastic scatter  Inelastic scatter  Non-elastic scatter  Neutron capture  Spallation 4 Overview of Neutron Physics Ref: Principles of Radiation Interaction, 22.101, fall 2006, MIT open courseware

5 5 Overview of Neutron Physics Ref: Principles of Radiation Interaction, 22.101, fall 2006, MIT open courseware

6 6 Overview of Neutron Physics Ref: Principles of Radiation Interaction, 22.101, fall 2006, MIT open courseware

7 7 Overview of Neutron Physics Ref: Principles of Radiation Interaction, 22.101, fall 2006, MIT open courseware

8 8 Overview of Neutron Physics For neutron detection using CR-39 detectors, the nuclear interactions involved are: Elastic scattering – recoil nuclei (mainly protons for our application) Non-elastic scattering – (n,p) or (n,α) reactions Spallation (fragmentation of the C and O atoms in the radiator into secondary hadrons and neutrons, due to highly energetic primary neutrons) Ref: Principles of Radiation Interaction, 22.101, fall 2006, MIT open courseware

9 9 N.B: I’ve seen this kind of tracks only 2 times in the past 3 years of experiments in different neutron/proton/carbon beams Overview of Neutron Physics 62 MeV/n C ions 4cm 20cm

10 Neutron Cross section on C and H 10 Neutron dosimetry with CR-39 detectors Chemical composition: PMMA: (C 5 0 2 H 8 ) n CR-39: (C 6 0 8 H) n C compensates for reduction in neutron cross section on H at E n > 10MeV

11 11 Correlation between LET and Energy Ref: Principles of Radiation Interaction, 22.101, fall 2006, MIT open courseware

12 12 Correlation between LET and Energy Ref: Principles of Radiation Interaction, 22.101, fall 2006, MIT open courseware Ref: S. Tavernier, Experimental Techniques in Nuclear and Particle Physics

13 What is LET nc measured in CR-39? 13 Etching time 60 min Alpha energy 6.1 MeV (Cf-252) Etching time 90 min Alpha energy 6.1 MeV (Cf-252) 10.0 µm ≈V Tmean *t = =22.9 µm 15.0 µm Residual energy=0 Residual energy=3.35MeV ≈V Tmean *t = =39.5 µm LET nc is the calculated from the V ratio (V t /Vb) and is an approximation of the lineal energy of the impinging ion

14 Dose calculations from the LET nc spectra 14 ICRP, 1991 Example of an LET nc spectrum measured in a carbon beam

15 Politrack ® instrument 15 CR-39 ® detector from RTP Politrack ® instrument

16 16 Politrack ® instrument

17 17 Politrack ® instrument A few examples of frames on a CR-39 detector Totally saturated detector

18 CR-39 detector analysis with Politrack ® 18 Automatic counting and geometrical analysis of the tracks by POLITRACK (a) Track filtering (account for dust particles or surface defects) (b) V t and LET nc and impinging angle determination (c) LET nc distribution (d) Dose Calculation => (a) (b) (c) (d)

19 In the PMMA radiator, the type of secondary particles produced is strongly dependent on the neutron beam energy (E n ): E n < 10 MeV : (n,p) reactions E n > 10 MeV : (n,p) reactions + (n,α) reactions + (n,d) reactions + (n,t) reactions http://www.oecd-nea.org/janis/ Neutron dosimetry with CR-39 detectors 19 Fragmentation of O and C atoms occur due to inelastic scattering and spallation reactions when E n > 10 MeV

20 Most of the present European dosimetry services (IRSN France, LANDAUER Europe, PSI Switzerland, ENEA Bologna in Italy) correlate the neutron dose with the track density. This results in a detector sensitivity that can vary by a factor 10 according to the neutron energy. Thus a prior knowledge of the energy composition of the neutron field is required. State of the Art 20 M. Caresana et al.

21 o Our approach is based on the capability of CR-39 to evaluate the average Linear Energy Transfer (LET) and the possibility to assess the dose from the average LET. (M. Caresana et al.) o The results is that when using this approach the detector response is more stable on a wide neutron energy range. o No or little prior knowledge of the neutron field is needed with this technique. The neutron field can thus be investigated directly with the average LET measurements done using the CR-39 detectors, acting as a low-resolution spectrometer. Novel approach 21

22 Dose measurement in a simulated workplace field at CERF facility at CERN 22 Fig 2a. LET distribution measured for the position CT 5 Fig 2b. LET distribution measured for the position CT12 Position Reference Dose (mSv) Measured Dose in CR-39 (mSv) CT-55.173.8 ± 1.4 CT-124.854.1 ± 0.5 Fig 1a. CERF irradiation facility

23 23 Testing the spectrometric capabilities of the Politrack ® 380µm 5µm 2 cm 285µm 3 cm CR-39 surface reconstruction from track parameters

24 24 Testing the spectrometric capabilities of the Politrack ® 2D distribution of the Absorbed dose (mGy) 2D distribution of the Dose Equivalent (mSv) Spatial resolution: 0.37 µm Pixel/Frame size : 285 µm * 380 µm Sensitive area : 70 * 79 pixels/frames (2 * 3 cm) 380µm 5µm 285µm

25 25 Primary reactions Secondary reactions Tertiary reactions Ref: Frenje JA. et al., First measurements of the absolute neutron spectrum using the magnetic recoil spectrometer at OMEGA. Rev Sci Instrum. 2008 Oct;79(10):10E502. doi: 10.1063/1.2956837. Applications for neutron spectrometry using CR-39 track detectors Magnetic Recoil Spectrometer at OMEGA laser facility, Laboratory for Laser Energetics, Rochester, NY

26 Conclusion 26 o CR-39 is acts as a low resolution spectrometer and a dosimeter at the same time o A relatively low cost o It is insensitive to stray radiation such as intense gamma rays pulses which are parasites to all active detection instruments o It’s limits however are it’s insensitivity to hadrons having a low-LET or high angle of incidence on the detector; thus reducing the response of the detector

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