Modane, 12/01/2005 Vitaly Kudryavtsev - JRA1 meeting 1 Background simulations: testing Monte Carlo codes V. A. Kudryavtsev Department of Physics and Astronomy.

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Presentation transcript:

Modane, 12/01/2005 Vitaly Kudryavtsev - JRA1 meeting 1 Background simulations: testing Monte Carlo codes V. A. Kudryavtsev Department of Physics and Astronomy University of Sheffield Working Group on Background Studies - N3 (BSNS) and JRA1 (WP2)

Modane, 12/01/2005 Vitaly Kudryavtsev - JRA1 meeting 2 Outline Neutrons from radioactivity in rock and their suppression by passive shielding. Neutrons from cosmic-ray muons. Gamma background and its suppression. Suppression of backgrounds by active veto. Conclusions.

Modane, 12/01/2005 Vitaly Kudryavtsev - JRA1 meeting 3 Neutron production by U/Th SOURCES-4A (Wilson et al. SOURCES4A, Technical Report LA MS, Los Alamos, 1999) - code to calculate neutron flux and energy spectrum arising from U/Th contamination in various materials. Problems: –Alphas below 6.5 MeV only; –Some cross-sections are missing (because the energy threshold for these reactions is higher than 6.5 MeV); –Cross-sections needed updating; Modifications to SOURCES: –6.5 MeV upper limit removed; –Cross-sections already present in the code library extended to higher energies using available experimental data; –Some cross-section updated according to recent experimental results (Na); –New cross-sections added ( 35 Cl, Fe, Cu); –Probability of transitions to the excited states at high energies of alphas are as at 6.5 MeV (overestimate neutron energy); –For new cross-sections - all transitions to the ground state only.

Modane, 12/01/2005 Vitaly Kudryavtsev - JRA1 meeting 4 Neutron production spectra Neutron production spectrum in NaCl (from modified SOURCES-4A): 60 ppb U, 300 ppb Th - mainly ( ,n). Neutron production rate in NaCl  cm -3 s -1 agrees with other calculations. Major problem: neutron energy spectrum in the laboratory (after propagation) is softer than measured at Modane (Chazal et al. Astropart. Phys. 9 (1998) 163; revised recently - Gerbier et al. TAUP2003), Gran Sasso (Arneodo et al. Nuovo Cimento A112 (1999) 819) and CPL (Korea) (Kim et al. Astropart. Phys. 20 (2004) 549) and also softer than other simulations. But - different types of rock make direct comparison difficult.

Modane, 12/01/2005 Vitaly Kudryavtsev - JRA1 meeting 5 Neutron production spectra SOURCES and GEANT4: Carson et al. Astropart. Phys. 21 (2004) simulation for Modane rock; triangles show the measurements (from concrete?) from Chazal et al. Astropart. Phys. 9 (1998) 163 (flux revised recently - Gerbier et al. TAUP2003). Neutron spectrum (Modane calculation) and its suppression in paraffin (propagation with MCNP) - Gerbier et al. Talk at TAUP2003: WorkShops/TAUP2003/Parallel/

Modane, 12/01/2005 Vitaly Kudryavtsev - JRA1 meeting 6 Neutron production spectra Energy spectrum of neutrons from 5.0 MeV alphas incident on aluminum oxide slab (left) and from 5.5 MeV alphas incident on magnesium slab (right) as calculated by SOURCES 4A (from SOURCES manual) and compared to measured data (Jacobs and Liskien, Annals of Nuclear Energy, 10 (1983) 541). 5.0 MeV alphas - Al 2 O MeV alphas - Mg (natural)

Modane, 12/01/2005 Vitaly Kudryavtsev - JRA1 meeting 7 Neutron spectra from rock Neutron spectrum at CPL - Kim et al. Astropart. Phys. 20 (2004) 549. Neutron spectra calculated for Gran Sasso (different halls and water contents in concrete) after propagation - MCNP - Wulandari et al. Astropart. Phys. 22 (2004) 313. Neutron propagation through rock and shielding: MCNP - Briesmeister (Ed.), MCNP - Version 4B (and later), LA M, LANL, 1997; GEANT4 - GEANT4 Collab., NIMA, 506 (2003) 250. Neutron spectrum at Gran Sasso - Arneodo et al. Nuovo Cimento, A112 (1999) 819.

Modane, 12/01/2005 Vitaly Kudryavtsev - JRA1 meeting 8 Neutron spectra from rock Measured and simulated (GEANT4 propagation) neutron spectra for IGEX (Ge dark matter detector - Canfranc laboratory) - no significant difference was found between simulations for soft (fission) and hard ( ,n) spectra - Carmona et al. Astropart. Phys. 21 (2004) 523. Neutron spectra from fission and ( ,n) reactions assumed in the simulations - Carmona et al. Astropart. Phys. 21 (2004) 523.

Modane, 12/01/2005 Vitaly Kudryavtsev - JRA1 meeting 9 Neutron spectra from rock Main feature in SOURCES absent (probably) in other calculations: –Accounting for transitions of the final nucleus to the excited states (GNASH calculations of probabilities) - reduces neutron energies. Are these cross-sections, transition probabilities and other features correct? The code was tested against measured spectra from various sources, but need more accurate measurements in underground labs (including neutron spectra). Main problems: cross-sections on many isotopes have not been measured; transition probabilities: what is the accuracy of calculations? Is there any other code available? Similar problems when calculating neutron production rate in detector components (including shielding) : we found a difference of about 50% for iron (70% for stainless steel) between neutron yield from SOURCES and from Heaton et al., Nucl. Geophys., 4 (1990) but the ( ,n) cross- section has been measured for 54 Fe only (among all other iron isotopes and almost all elements in the steel).

Modane, 12/01/2005 Vitaly Kudryavtsev - JRA1 meeting 10 Neutron propagation and detection MCNP and GEANT4: substantial difference, probably (partly) due to the difference in initial neutron spectra (and geometry). GEANT4: Carson et al. Astropart. Phys. 21 (2004) >10 5 suppression after 50 g/cm 2 of PE. MCNP (detection in CRESST): Wulandari et al. Talk at IDM2004 (10 4 suppression):

Modane, 12/01/2005 Vitaly Kudryavtsev - JRA1 meeting 11 Neutron propagation and detection Effect of initial neutron spectrum - GEANT4: Carson et al. Astropart. Phys. 21 (2004) 667. Neutron spectrum suppression - MCNP: Gerbier et al. Talk at TAUP2003: TAUP2003/Parallel/ Neutron propagation through the shielding with the two codes is needed using the same geometry and the same input neutron spectrum - ongoing.

Modane, 12/01/2005 Vitaly Kudryavtsev - JRA1 meeting 12 Muon-induced neutrons Inputs: –Muon rate - measurements at a particular underground site. –Muon spectrum and angular distribution (normalised to the total rate) - simulations or measurements (if available) - not a problem (we are using MUSUN code - Kudryavtsev et al. NIMA, 505 (2003) 688). –Neutrons from muons - production, propagation, detection together with all other particles (muon-induced cascades): GEANT4 (GEANT4 Coll. NIMA, 506 (2003) 250) or FLUKA (Fasso et al. Proc. MC2000 Conf., Lisbon, 2000, p. 159; ibid. p. 995). Important: all particles should be produced, propagated and detected with one code to look for simultaneous detection of neutrons and other particles, such as photons, electrons, muons, hadrons. For dark matter experiments: FLUKA does not generate nuclear recoils in a realistic way.

Modane, 12/01/2005 Vitaly Kudryavtsev - JRA1 meeting 13 Modified GEANT3 and FLUKA Modified GEANT3 - correct calculation of muon inelastic scattering (Karlsruhe group). Good agreement between GEANT3 (Gerbier, talk at IDM2004) and FLUKA, although GEANT3 does not simulate photoproduction.

Modane, 12/01/2005 Vitaly Kudryavtsev - JRA1 meeting 14 Muon-induced neutrons: GEANT4 vs FLUKA Comparison between different models in GEANT4 and FLUKA - Bauer et al. Proc. IDM2004,

Modane, 12/01/2005 Vitaly Kudryavtsev - JRA1 meeting 15 Muon-induced neutrons: GEANT4 vs FLUKA Neutron production rate in (CH 2 ) n (liquid scintillator): Araujo et al., hep-ex/ ; FLUKA (Paper 1) - Kudryavtsev et al. NIMA, 505 (2003) 688; FLUKA (Paper 2) - Wang et al. Phys. Rev. D, 64 (2001)

Modane, 12/01/2005 Vitaly Kudryavtsev - JRA1 meeting 16 Muon-induced neutrons: processes Contribution of different processes: real photonuclear disintegration dominates in GEANT4 at all energies and for (almost) all materials. GEANT4: Araujo et al. FLUKA: Wang et al.

Modane, 12/01/2005 Vitaly Kudryavtsev - JRA1 meeting 17 Muon-induced neutrons: A-dependence Contribution of different processes in various materials - GEANT4: Araujo et al. A-dependence of neutron production rate - GEANT4: Araujo et al., FLUKA: Kudryavtsev et al. FLUKA gives twice as many neutrons compared to GEANT4 in most materials tested.

Modane, 12/01/2005 Vitaly Kudryavtsev - JRA1 meeting 18 Muon-induced neutrons: spectrum and lateral distribution Neutron production spectrum - GEANT4: Araujo et al., FLUKA: Wang et al. ; data - LVD: LVD Collab., Proc. 26 ICRC (Salt Lake City, 1999), vol. 2, p. 44; hep-ex/ Neutron lateral distribution (from muon track) - GEANT4: Araujo et al., FLUKA: Kudryavtsev et al. ; data - LVD: Proc. 26 ICRC; hep-ex/ Simulations did not include detector specific features.

Modane, 12/01/2005 Vitaly Kudryavtsev - JRA1 meeting 19 Muon-induced neutrons: problems Differential cross-section of neutron production in thin targets for 190 GeV muons (E n >10 MeV) Upper (thick) histograms - GEANT4; dashed line - FLUKA (Araujo et al.); data - NA55 (Chazal et al. NIMA, 490 (2002) 334). Other data for lead (Bergamasco et al. Nuovo Cim. A, 13 (1973) 403; Gorshkov et al. Sov. J. Nucl. Phys., 18 (1974) 57; see Wulandari et al., hep- ex/ for analysis) do not show so large discrepancy with simulations.

Modane, 12/01/2005 Vitaly Kudryavtsev - JRA1 meeting 20 Geometry lead C 10 H 20 n  salt xenon air

Modane, 12/01/2005 Vitaly Kudryavtsev - JRA1 meeting 21 Spectra in the laboratory Neutron spectra in the lab before and after shielding - GEANT4: Araujo et al.; also Araujo&Kudryavtsev, talk at IDM2004; FLUKA: Kudryavtsev et al. - good agreement for all energies of interest (within 50%).

Modane, 12/01/2005 Vitaly Kudryavtsev - JRA1 meeting 22 Events in xenon detector Nuclear recoil event rate as a function of measured energy (quenching = 0.2 for xenon) - GEANT4 and FLUKA: Araujo et al. - good agreement (within 30%). Energy spectrum of all events - GEANT4 and FLUKA: Araujo et al. Only <10% of nuclear recoil events contain nuclear recoils only; others have large energy deposition from other particles. To estimate the background from nuclear recoils only, all particles should be produced, propagated and detected.

Modane, 12/01/2005 Vitaly Kudryavtsev - JRA1 meeting 23 Problems with FLUKA FLUKA does not treat low- energy nuclear recoils realistically. Kerma factors (equivalent to the average energy deposition) are used to generate an energy deposition at the neutron interaction point. This may be ok for statistical analysis (good agreements with GEANT4 even for nuclear recoil rates and spectra) but potentially may be a problem. More data (with simulations) are welcome, in particular from LVD, SNO, Kamland and other experiments.

Modane, 12/01/2005 Vitaly Kudryavtsev - JRA1 meeting 24 Gamma background Gamma fluxes from radioactivity in rock (NaCl: 60 ppb U, 300 ppb Th, 1300 ppm K) simulated with GEANT4: Carson et al., submitted to NIMA; see also talk at IDM2004: A - rock/cavern interface; B, C, D, E - after 5, 10, 20, 30 cm of lead; F - after 20 cm of lead and 40 g/cm 2 of CH 2 Energy deposition spectra in 250 kg xenon from gammas simulated with GEANT4: Carson et al.: A -from 222 Rn (10 Bq/m 3 ); B- ultra-low background PMTs - Hamamatsu R8778; C - 85 Kr (5 ppb); D - copper vessel (0.02 ppb, 350 kg); E (F) - from rock after 10 (20) cm of lead and 40 g/cm 2 of CH 2.

Modane, 12/01/2005 Vitaly Kudryavtsev - JRA1 meeting 25 Veto performance Veto efficiency for neutron rejection (from detector components): 250 kg of xenon; measured energy keV; veto - Gd loaded liquid scintillator (40 g/cm 2 ); GEANT4: Carson et al. Submitted to NIMA. Circles - detection of proton recoils + neutron capture; triangles - gammas from n-capture only. Veto efficiency for neutron rejection (from detector components) as a function of veto thickness. Detector kg of xenon; measured energy keV; veto - Gd loaded (0.2%) liquid scintillator; gammas from n-capture only. GEANT4: Carson et al. Submitted to NIMA.

Modane, 12/01/2005 Vitaly Kudryavtsev - JRA1 meeting 26 Conclusions Neutron production: –large uncertainties in the neutron energy spectrum. More measurements underground are needed. –Better knowledge of ( ,n) cross-sections and transition probabilities to the excited states is required for some materials. –Is there any other code (not SOURCES) publicly available? Low-energy neutron propagation and detection: –MCNP vs GEANT4 - need more tests with the same geometry, same initial neutron spectra etc. Muon-induced neutrons: –FLUKA and GEANT4 (also modified GEANT3) agree within a factor of 2 (or even better). –Most experimental data (although with large uncertainties) are also in agreement with simulations within similar factor. –Some data show significantly larger neutron production rate in heavy materials. Gammas: –Physics is very well known and surprises are not expected but…