EFNUDAT Slow and Resonance Neutrons, Budapest (HU), Sep. 23-25, 2009 1 VERDI a double (v, E) fission-fragment fragment spectrometer S. Oberstedt, R. Borcea,, Th. Gamboni,, W. Geerts, F.-J. Hambsch, A. Oberstedt 1), M. Vidali 1 School of Science and Technology, Örebro University, S-70182 Örebro IRMM - Institute for Reference Materials and Measurements Geel - Belgium http://irmm.jrc.ec.europa.eu/ http://www.jrc.ec.europa.eu/
EFNUDAT Slow and Resonance Neutrons, Budapest (HU), Sep. 23-25, 2009 2 o Motivation o Concept of the TOF spectrometer VERDI o The VERDI energy side o The VERDI timing side o First experimental results o Summary & Outlook
Motivation EFNUDAT Slow and Resonance Neutrons, Budapest (HU), Sep. 23-25, 2009 3 Nuclear Energy Agency IAEA - INDC Nucl. Sci. Committee NEA Databank WPEC: Working Party for Evaluation Co-operation JEFF: Joint European Fission + Fusion datafile BROND ENDF JEFF WPEC CENDL JENDL
Motivation EFNUDAT Slow and Resonance Neutrons, Budapest (HU), Sep. 23-25, 2009 4 Reliable predictions on fission product yields relevant in modern nuclear applications (GEN-IV, ADS ) Radio-toxicity of the nuclear waste Decay heat calculations Delayed neutron yields relevant during reactor operation o Prediction of fission-fragment mass and kinetic energy distributions o Emission spectrum and multiplicity (as a function of fragment mass) of prompt γ-rays and neutrons o Delayed neutron emission pre-cursor yields
Fission-fragment characteristics EFNUDAT Slow and Resonance Neutrons, Budapest (HU), Sep. 23-25, 2009 5 2E measurement with a twin Frisch-grid ionisation chamber: Pre-neutron fragment masses and total kinetic energy iteratively determined Using known prompt neutron emission data (multiplicity, TXE dependence) Experimental neutron data only for a few isotopes Mass resolution usually worse than 4 amu
Fission-fragment characteristics EFNUDAT Slow and Resonance Neutrons, Budapest (HU), Sep. 23-25, 2009 6 235 U(n, f) @ 10 ev 10 1 IR M M exp.data(th) E=10 ev S1 10 0 S2 SL S1+S2+SL Y% 10-1 10-2 10 1 235 U(n,f) Fission cross section (b) 10 0 10-1 10-2 V A =5.40 MeV; hω A =1.00:V I =2.42 MeV;hω I =1.00 MeV V S1 =6.80 MeV; hω S1 =1.15 MeV V S2 =6.07 MeV; hω S2 =0.70 MeV V SL =8.70 MeV; hω SL =2.00 MeV exp.exfor ENDF/B-VI; Present evaluation IRMM S1 S2 SL 10-3 60 80 100 120 140 160 180 200 A f Are quantitative predictions of fission fragment yields possible? 10-3 10-2 10-1 10 0 E n (MeV)
Fission-fragment characteristics EFNUDAT Slow and Resonance Neutrons, Budapest (HU), Sep. 23-25, 2009 7 o 238 U (n, f) @ E n = 0.9 2 MeV E* 5.8 MeV E* 6.1 MeV E. Birgersson et al., Nucl. Phys. A817 (2009) 1-34
Fission-fragment characteristics EFNUDAT Slow and Resonance Neutrons, Budapest (HU), Sep. 23-25, 2009 8 Has it to do with the 2E-technique? Is prompt neutron (ν p ) emission well under control? Uncertainty due to iterative neutron correction in a 2E-experiment... Is the dependence of ν p on excitation energy incorrectly treated? Extra/interpolation of prompt neutron data from neighbouring nuclei not correct? microscopic neutron emission data do not fit to results from integral experiments (even for 235 U!!!) although average emission energy (ε ν ) differs by only 50 kev Is the multi-modal fission model not correct?
VERDI the concept EFNUDAT Slow and Resonance Neutrons, Budapest (HU), Sep. 23-25, 2009 9 Simultaneous measurement of kinetic energy and velocity of both fission fragments 2v pre-neutron masses, A i * (i = l, h), TKE v,e post-neutron masses, A i, E k,i (i = l, h) ν i (A i *) from the difference A i * - A i TXE(A i ) delayed decay modes of fission fragments Cosi Fan Tutte (ILL)
VERDI basic ingredients EFNUDAT Slow and Resonance Neutrons, Budapest (HU), Sep. 23-25, 2009 10 Goals: spectrometer efficiency ε 0.005 0.01 for a mass resolution of A/ A 100 High resolution energy detector ( E/E = 0.006) High precision (transmission) time pick-up with τ < 150 ps @ L = 50cm radiation hardness of the time pick-up Cosi Fan Tutte (ε 5 10-5 )
VERDI the energy side EFNUDAT Slow and Resonance Neutrons, Budapest (HU), Sep. 23-25, 2009 11 o Axial ionisation chamber: Simple to construct and to use Split electrodes allow element identification (cf. LOHENGRIN) No radiation damage Very good intrinsic energy resolution Timing characteristics??? Difficult to make a large area detector Energy loss in the entrance window o Large area silicon detectors: Relatively cheap Easy to use Excellent pulse height stability Excellent energy resolution Promising timing characteristics Subject to radiation damage
VERDI the energy side EFNUDAT Slow and Resonance Neutrons, Budapest (HU), Sep. 23-25, 2009 12 PIPS (area: 900 mm 2 ) 239 Pu, 241 Am, 244 Cm Energy resolution for α- particle kinetic energy: δe = 0.006 close to our design specifications for fission-fragments
VERDI the timing side EFNUDAT Slow and Resonance Neutrons, Budapest (HU), Sep. 23-25, 2009 13 o µ-channel plate detectors: Very good intrinsic timing characteristics Difficult to handle Requires excellent vacuum p < 10-6 mbar Subject to radiation damage (especially in an intense neutron field)??? Difficult to build o Diamond detectors (pc/sc-cvdd): New detector material Relatively few experimental results Pulse height stability of pccvdd difficult to predict and to maintain Difficult to produce (artificial) single-crystal diamonds Promising timing characteristics (with Ni-ion @ 30 MeV/u t 30 ps) Never tested with fission fragments (0.5 MeV/u < v FF < 2 MeV/u) Radiation hard
CVD diamonds EFNUDAT Slow and Resonance Neutrons, Budapest (HU), Sep. 23-25, 2009 14 o Chemical vapour deposited (CVD) diamond o Working principle similar to a silicon-detectors o Poly-crystalline (pc) CVDD available o No pulse-height resolution for pccvdds o Ultra-fast timing characteristics Also for low-energy heavy ions?
pccvdd - material properties EFNUDAT Slow and Resonance Neutrons, Budapest (HU), Sep. 23-25, 2009 15 triple α-source irradiated with a 90 Sr/ 90 Y β-source (3MBq, 72h)
pccvddd pulse-height stability EFNUDAT Slow and Resonance Neutrons, Budapest (HU), Sep. 23-25, 2009 16 Pulse height stability against radiation damage up to a fissionfragment dose of at least 1.2 10 9 Including an α-particle dose of 4 10 10 and a fast neutron dose of about 5 10 10
Experimental set-up EFNUDAT Slow and Resonance Neutrons, Budapest (HU), Sep. 23-25, 2009 17 (v, E) 252 Cf PIPS, 300 µm pccvddd, 100 µm 225 mm pccvdd material size: 1 1 cm 2 thickness: 100 µm
Pulse-height analysis EFNUDAT Slow and Resonance Neutrons, Budapest (HU), Sep. 23-25, 2009 18 CVD pulse height spectrum PIPS pulse height spectrum no coincidence coincidence with 7 PIPS no coincidence coincidence with 7 PIPS
pccvddd - Intrinsic timing resolution EFNUDAT Slow and Resonance Neutrons, Budapest (HU), Sep. 23-25, 2009 19 252 Cf pccvddd, 100 µm pccvddd, 100 µm 95 mm pccvdd material size: 1 1 cm 2 thickness: 100 µm
Determination of the timing resolution EFNUDAT Slow and Resonance Neutrons, Budapest (HU), Sep. 23-25, 2009 20 o By means of a Monte-Carlo simulation o Experimental fission-fragment distribution o Post-neutron fragment yield o Post-neutron fragment kinetic energy o Geometry of the detector set-up o Variation of the time-resolution parameter until reproduction of the measured time distribution
pccvddd - Intrinsic timing resolution EFNUDAT Slow and Resonance Neutrons, Budapest (HU), Sep. 23-25, 2009 21
VERDI - the timing resolution EFNUDAT Slow and Resonance Neutrons, Budapest (HU), Sep. 23-25, 2009 22 (v, E) 252 Cf PIPS, 300 µm pccvddd, 100 µm 330 mm pccvdd material size: 1 1 cm 2 thickness: 100 µm Up to 7 PIPS detectors ORTEC 900 mm 2 CANBERRA (same specs.) CANBERRA (450 mm 2 ) Eurysis (40 mm 2 )
VERDI - the timing resolution EFNUDAT Slow and Resonance Neutrons, Budapest (HU), Sep. 23-25, 2009 23 Ortec PIPS 900 mm 2 Eurysis 40 mm 2 t < 1.0 ns t < 0.6 ns
VERDI data analysis EFNUDAT Slow and Resonance Neutrons, Budapest (HU), Sep. 23-25, 2009 24 Energy calibration from reference distributions published in The Nuclear Fission Process Channel-to-time conversion making use of a trend established from 233,235 U and 239 Pu data Pulse-height defect correction applied (Schmitt calibration)
VERDI FF distributions EFNUDAT Slow and Resonance Neutrons, Budapest (HU), Sep. 23-25, 2009 25 Eurisys 40 mm 2
VERDI challenges EFNUDAT Slow and Resonance Neutrons, Budapest (HU), Sep. 23-25, 2009 26 Canberra t-pips 450 mm 2 preliminary results
VERDI - the design EFNUDAT Slow and Resonance Neutrons, Budapest (HU), Sep. 23-25, 2009 27 L = 50 cm 2 x 19 PIPS detectors (450 mm 2 ) pccvdd (or MCP) ultra-fast time pick-up detectors set-up can be handled with NIM electronics development of an AMUX + tag-word coder module
Summary EFNUDAT Slow and Resonance Neutrons, Budapest (HU), Sep. 23-25, 2009 28 Post-neutron mass resolution A = 2.2-2.8 achieved pccvdd detectors may be used for fissionfragment timing radiation hardness of the pccvdd start trigger proven spectrometer efficiency ε 0.5%
Summary EFNUDAT Slow and Resonance Neutrons, Budapest (HU), Sep. 23-25, 2009 29 Fission fragment timing resolution τ < 300 ps possible VERDI with mass resolution A 1.5 possible To reach at τ < 200 ps seems challenging VERDI will allow the consistent measurement of pre- and post neutron fission fragment data Prompt neutron emission data Y(A*, TKE; TXE)
The near future EFNUDAT Slow and Resonance Neutrons, Budapest (HU), Sep. 23-25, 2009 30 First experiment @ KFKI beginning 2010 (EFNUDAT) (v, E) experiment: 235 U(n th, f) Y(A, E k ) with a 1 1 cm 2 4-fold segmented pccvddd Φ n,th 5 10 7 /s/cm 2 : c th > 2 FF/s or 10 6 FF/(120 h) per detector prompt fission γ-rays using the CVDD detector as fission-trigger ( A. Oberstedt et al.) pccvdd transmission detector under investigation thickness around 5 µm, 8-fold segmented first (weak) α-particle signals extracted Extremely difficult to achieve electrical contact Test with fission fragments soon o Construction of a µ-channel plate detector
Nothing without a good team! EFNUDAT Slow and Resonance Neutrons, Budapest (HU), Sep. 23-25, 2009 31 R. Borcea F.-J. Hambsch Van de Graaff technical team A. Oberstedt Örebro University
EFNUDAT Slow and Resonance Neutrons, Budapest (HU), Sep. 23-25, 2009 32