Measurements of the 238U radiative capture cross section using C6D6

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Presentation transcript:

Measurements of the 238U radiative capture cross section using C6D6 F. Mingrone on behalf of the n_TOF Collaboration ANDES Final Meeting Bruxelles – October 21, 2013

Motivations NEA High Priority Request List Advanced nuclear systems Improvement in the design of Nuclear fuel cycles EXFOR DATABASE: 25 datasets in the resolved resonance region and a few less in the unresolved BUT still inconsistencies for the capture cross section up to 25 keV EC-JRC-IRMM Gelina with C6D6 detection system NEA High Priority Request List UNCERTAINTY IN THE CROSS SECTION BELOW 2% Nea high priority list n_TOF with TAC detection system n_TOF with C6D6 detection system

EXPERIMENTAL TECHNIQUE Detector Flight path L  Sample under analysis Proton beam Neutron beam  Spallation target

EXPERIMENTAL TECHNIQUE Detector Flight path L  Sample under analysis Proton beam Neutron beam  Spallation target En [eV] FWHM [cm] DEn [eV] 1 3 3.2 × 10-4 10 3.2 × 10-3 102 4 4.3 × 10-2 103 5 5.4 × 10-1 104 11 105 27 2.9 × 102 106 49 5.3 × 103

EXPERIMENTAL TECHNIQUE Using a Time of Flight (TOF) technique, capture cross section is determined through the measurement of the reaction yield YR(En): N: normalization factor to obtain an absolute capture yield Cw: weighted counts background subtracted F: incident neutron fluence ε = k x Ec: detection efficiency The experimental yield can be expressed in terms of total (stot) and capture (sg) cross section:

EXPERIMENTAL TECHNIQUE For capture measurements, detection efficiency have to be independent from g-spectrum multiplicity and from g-ray energy distribution Total Absorption Detection eg ~ 100 % 4p geometry detectors Total Energy Detection Low detection efficiency eg Low solid angle Basically we want to detect only one gamma ray per cascade

n_TOF facility at CERN CERN Experiment PS213

n_TOF facility: characteristics Proton beam momentum 20 GeV/c Intensity (dedicated mode) 7 × 1012 protons/pulse Repetition frequency 1 pulse/2.4 s Pulse width 7 ns (rms) Neutrons/proton 300 Lead target dimensions =60 cm, h=40 cm Cooling material H2O Moderation material Borated Water (H2O + 1.28% H3BO3) Moderator thickness in the exit face 1 cm cooling material + 4 cm moderator

Radiative capture on 238U campaign SAMPLE DATE (YEAR 2012) PROTONS 238U 10 d: March 29 – April 03, April 25 – 27, April 30 – May 02; Filters – 7 d: April 5 – 6, April 11 – 16 7.85 × 1017 + 1.2 × 1018 Sample Out 6 d: March 28 – 2; Filters – 3 d: April 9 – 11 6.271 × 1016 + 1.64 × 1017 238U packing 2 d: April 21 – 22 9.65 × 1016 Beam off 0.25 d: March 28, April 5, April 11 Calibrations Pb 2d: April 03 – 04; Filters – 2 d: April 8 – 9 1.50 × 1017 + 1.53 × 1017 C (5 mm) 3 d: April 4 – 5, April 17; Filters – 2 d: April 7 – 8 1.46 × 1017 + 1.66 × 1017 C (10 mm) 2 d: April 19 – 20; Filters – 3 d: April 28 – 30 9.71 × 1016 + 1.11 × 1017 Au (50 µm) 2 d: April 5, April 16 4.86 × 1016 Au (300 µm) 2 d: April 17 – 18; Filters – 2 d: April 27 – 28 8.33 × 1016 + 9.93 × 1016 Ag 1 d: May 02 1.60 × 1016 238U(n,g) – TOT: 17 days

Radiative capture on 238U campaign SAMPLE DATE (YEAR 2012) PROTONS 238U 10 d: March 29 – April 03, April 25 – 27, April 30 – May 02; Filters – 7 d: April 5 – 6, April 11 – 16 7.85 × 1017 + 1.2 × 1018 Sample Out 6 d: March 28 – 2; Filters – 3 d: April 9 – 11 6.271 × 1016 + 1.64 × 1017 238U packing 2 d: April 21 – 22 9.65 × 1016 Beam off 0.25 d: March 28, April 5, April 11 Calibrations Pb 2d: April 03 – 04; Filters – 2 d: April 8 – 9 1.50 × 1017 + 1.53 × 1017 C (5 mm) 3 d: April 4 – 5, April 17; Filters – 2 d: April 7 – 8 1.46 × 1017 + 1.66 × 1017 C (10 mm) 2 d: April 19 – 20; Filters – 3 d: April 28 – 30 9.71 × 1016 + 1.11 × 1017 Au (50 µm) 2 d: April 5, April 16 4.86 × 1016 Au (300 µm) 2 d: April 17 – 18; Filters – 2 d: April 27 – 28 8.33 × 1016 + 9.93 × 1016 Ag 1 d: May 02 1.60 × 1016 BACKGROUND – TOT: 14.5 days

Radiative capture on 238U campaign SAMPLE DATE (YEAR 2012) PROTONS 238U 10 d: March 29 – April 03, April 25 – 27, April 30 – May 02; Filters – 7 d: April 5 – 6, April 11 – 16 7.85 × 1017 + 1.2 × 1018 Sample Out 6 d: March 28 – 2; Filters – 3 d: April 9 – 11 6.271 × 1016 + 1.64 × 1017 238U packing 2 d: April 21 – 22 9.65 × 1016 Beam off 0.25 d: March 28, April 5, April 11 Calibrations Pb 2d: April 03 – 04; Filters – 2 d: April 8 – 9 1.50 × 1017 + 1.53 × 1017 C (5 mm) 3 d: April 4 – 5, April 17; Filters – 2 d: April 7 – 8 1.46 × 1017 + 1.66 × 1017 C (10 mm) 2 d: April 19 – 20; Filters – 3 d: April 28 – 30 9.71 × 1016 + 1.11 × 1017 Au (50 µm) 2 d: April 5, April 16 4.86 × 1016 Au (300 µm) 2 d: April 17 – 18; Filters – 2 d: April 27 – 28 8.33 × 1016 + 9.93 × 1016 Ag 1 d: May 02 1.60 × 1016 NORMALIZATION – TOT: 3.5 days

Radiative capture on 238U campaign SAMPLE DATE (YEAR 2012) PROTONS 238U 10 d: March 29 – April 03, April 25 – 27, April 30 – May 02; Filters – 7 d: April 5 – 6, April 11 – 16 7.85 × 1017 + 1.2 × 1018 Sample Out 6 d: March 28 – 2; Filters – 3 d: April 9 – 11 6.271 × 1016 + 1.64 × 1017 238U packing 2 d: April 21 – 22 9.65 × 1016 Beam off 0.25 d: March 28, April 5, April 11 Calibrations Pb 2d: April 03 – 04; Filters – 2 d: April 8 – 9 1.50 × 1017 + 1.53 × 1017 C (5 mm) 3 d: April 4 – 5, April 17; Filters – 2 d: April 7 – 8 1.46 × 1017 + 1.66 × 1017 C (10 mm) 2 d: April 19 – 20; Filters – 3 d: April 28 – 30 9.71 × 1016 + 1.11 × 1017 Au (50 µm) 2 d: April 5, April 16 4.86 × 1016 Au (300 µm) 2 d: April 17 – 18; Filters – 2 d: April 27 – 28 8.33 × 1016 + 9.93 × 1016 Ag 1 d: May 02 1.60 × 1016 ENTIRE CAMPAIGN: 35 days

EXPECTED RADIOACTIVITY Samples Enriched metallic uranium rectangular plate (53×30 mm2, 235 µm thick) enveloped inside a 20 mm aluminum and a 25 mm kapton thick foils. Provided by the EC-JRC-IRMM MASS 6.125 ± 0.002 g 9.6×10-4 atoms/barn % 238 U 99.99 % % 235 U < 11 ppm % 233-234-236 U < 1 ppm each EXPECTED RADIOACTIVITY 12.4 kBq/g (76 kBq) Isotopic analysis done @ IRMM in 1984

ATOMIC DENSITY [atoms/barn] Samples The other samples analyzed have been chosen with geometry as similar as possible to that of the 238U. 197Au SAMPLE SIZE [mm] MASS [g] ATOMIC DENSITY [atoms/barn] 197Au 53.30 × 29.65 9.213 1.773 10-3 Pb 53.77 × 30.19 9.44 1.725 10-3 C 53.35 × 30.20 28.89 8.94 10-2 Fe 53.71 × 30.22 3.225 2.13 10-3 Ag 53.75 × 30.30 4.620 1.59 10-3 C natPb

New 2012 measurement: EXPERIMENTAL SET–UP Two different setups for capture measurements Total Absorption Calorimeter 40 BaF2 crystals in a 4p geometry Detects the entire g cascade (together with background n) Two C6D6 scintillation detectors Optimized for an extremely low neutron sensitivity Only one g–ray detected per cascade  Total Energy Detection System with PHWT BaF2 C6D6 C6D6 NEUTRON FLUX

Calibrations 137Cs 88Y Am-Be accurate study of the calibrations between the flash-ADC channels and the deposited energy was performed on a weekly basis using three standard sources: 137Cs (661.7 keV), 88Y (0.898 and 1.836 MeV) and Am/Be (4.44 MeV). Comparing the different calibration spectra for each isotope, we notice that they are not stable, and for this reason we extracted six calibration lines from the different measurements made.

Calibrations 137Cs 88Y Am-Be

Simulated Detectors Response: Uniform emission Detector response convoluted with the experimental resolution of the det

Simulated Detectors Response: Exponential attenuation

Weighting Functions 238U 197Au

Flux stability

C6D6 counts stability 238U first resonance

C6D6 counts stability 238U first resonance

C6D6 counts stability

238U(n,g)239U: TOF spectra Linee energia

Background subtraction

Background subtraction Natural radioactivity Empty Frame and Dummy Scattered neutrons In-beam gamma rays

Background subtraction Natural radioactivity Empty Frame and Dummy Scattered neutrons In-beam gamma rays EF U Pb Au C

Background subtraction Natural radioactivity

Background subtraction Natural radioactivity Empty Frame and Dummy Scattered neutrons In-beam gamma rays

Background subtraction Empty Frame and Dummy Natural radioactivity Scattered neutrons In-beam gamma rays

Background subtraction Natural radioactivity Empty Frame and Dummy Scattered neutrons In-beam gamma rays

Background subtraction Scattered neutrons 50 bin per decade

Background subtraction Scattered neutrons

Background subtraction Scattered neutrons

Background subtraction Scattered neutrons 50 bin per decade

Background subtraction Scattered neutrons – 238U – Scattered neutrons

Background subtraction Natural radioactivity Empty Frame and Dummy Scattered neutrons In-beam gamma rays

Background subtraction Scattered neutrons – 238U – natPb

Background subtraction – 238U background subtracted

Normalization: saturated resonance technique

197Au YIELD: analysis validation

197Au YIELD: analysis validation

197Au YIELD: analysis validation

197Au YIELD: analysis validation

197Au YIELD: analysis validation

197Au YIELD: analysis validation

197Au YIELD: analysis validation

197Au YIELD: analysis validation

197Au YIELD: analysis validation

197Au YIELD: analysis validation

197Au YIELD: analysis validation

197Au YIELD: analysis validation

238U CAPTURE YIELD

238U CAPTURE YIELD

238U CAPTURE YIELD

238U CAPTURE YIELD

238U CAPTURE YIELD

238U CAPTURE YIELD

238U CAPTURE YIELD

238U CAPTURE YIELD

238U CAPTURE YIELD

238U CAPTURE YIELD

238U CAPTURE YIELD

238U CAPTURE YIELD

238U CAPTURE YIELD

238U CAPTURE YIELD

238U CAPTURE YIELD

238U CAPTURE YIELD

CONCLUSIONS Accurate data rejection and calibrations (6 calibration lines extracted) Accurate background subtraction (analysis of the background level with filters ongoing) SOURCE OF UNCERTAINTY 1 eV < En < 1-3 keV THERMAL + URR Sample mass 0.03% Neutron flux (shape in En) ~0.5% Neutron flux (abs. value) [i.e. normalization] <1% Background (at resonance peek) 0-1% 4-5% Overall 1.1-1.5% 5-6%

Thank you! Federica Mingrone mingrone@bo.infn.it Università di Bologna, Dipartimento di Fisica e Astronomia Istituto Nazionale di Fisica Nucleare, Sezione di Bologna mingrone@bo.infn.it

BACKUP

238U(n, g)239U: TOF spectra Linee energia

Background subtraction

Unresolved Resonance Region: GOLD

Yield Au: thermal

Yield Au: 0-200 eV

Yield 238U: 0-500 eV

Counting statistic uncertainties 100 bin per decade