Nuclear reactions and physical models for neutron activation analysis

Trkov, A.; Radulović, Vladimir

doi:10.1007/s10967-014-3892-5

Cited by 19 publications

(11 citation statements)

References 20 publications

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“…It can also be observed that It can be seen that the peak of the Maxwellian‐spectrum is at about 6.246E‐01 and 6.256E‐01 eV, respectively. The shape beyond the Maxwellian 28 is a typical (1/E) shape with dips at major resonances of 232 Th and 238 U. Also, the average flux was generated from simulation using ENDF/B VIII.0 data library was normalized and flux per unit lethargy has been plotted, as shown in Figure 4B.…”

Section: Resultsmentioning

confidence: 99%

Neutronic and burn‐up calculations of the ( ThO2‐UO2 ) pin cell benchmark using DRAGON5 and MCNP6 .2 codes with ENDF / B‐VIII .0 nuclear data library

et al. 2021

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Summary A (ThO2‐UO2) fuel pin benchmark, consisting of 75 w/o Th and 25 w/o U, was utilized for analysis of depletion and inventory of the fuel for the pressurized water reactor (PWR) pin‐cell model. To perform this study and evaluate cross‐section data, the new version VIII.0 of the ENDF/B nuclear data library was utilized to generate a data set in ACE (A Compact ENDF) format at different temperatures (583.1, 600, 621.1, and 900 K), utilizing NJOY2016 and MAKXSF6.2 codes to process the data at the specific temperatures. In this paper, the infinite multiplication factor (kinf), neutron energy flux spectrum (utilizing 172 energy groups), the concentrations and activities of the most important products of fission, the actinide radionuclides accumulated in the pin‐cell, and the total radioactivity were calculated and compared, utilizing the MCNP6.2 and DRAGON5 codes. Furthermore, the burn‐up (BU) dependent behavior of the PWR thorium pin‐cell was validated and compared with the reference results obtained utilizing the CASMO‐4, MIT‐MOCUP, and INEEL‐MOCUP codes. The results of this study show good agreements between all codes analysed.

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Section: Resultsmentioning

confidence: 99%

Neutronic and burn‐up calculations of the ( ThO2‐UO2 ) pin cell benchmark using DRAGON5 and MCNP6 .2 codes with ENDF / B‐VIII .0 nuclear data library

et al. 2021

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“…Due to the shape of the (n, γ ) cross section of cadmium, the transmission characteristics of a cadmium shield can be described in good approximation by a step function, whereby neutrons below the cadmium cut-off energy E Cd (thermal neutrons) are considered as completely absorbed, while neutrons with energy above E Cd (epithermal and fast neutrons) are fully transmitted. The exact value of E Cd depends on the particular geometry and wall thickness of the cadmium case [38]. The value of E Cd = 0.55 eV is typically used and was adopted in our experiment.…”

Section: Thermal-neutron Cross Section and Resonance Integral Calcmentioning

confidence: 99%

“…This is corrected by the cadmium transmission factor F Cd , defined as the ratio between the epithermalactivation rates with and without the cadmium shield. F Cd differs from unity only for a small number of nuclides [38] and because no values of F Cd were found in the literature for the relevant reactions 53 Mn(n, γ ) and 59 Co(n, γ ), during the data evaluation it was assumed to be F Cd = 1 and thus R epi ≈R epi .…”

Section: Thermal-neutron Cross Section and Resonance Integral Calcmentioning

confidence: 99%

Neutron capture cross section of Mn53 from irradiation with cold and reactor neutrons

et al. 2020

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The neutron capture cross section of 53 Mn was measured with cold and reactor neutrons by the activation method, relative to the well-known cross section of 59 Co. Three targets containing a total of ≈10 18 atoms 53 Mn in the form of chloride salt were prepared using a stock solution obtained from activated accelerator waste in the course of the ERAWAST initiative at Paul Scherrer Institute, Switzerland (PSI). Natural cobalt salt was added to the sample material as an internal neutron flux monitor. The total numbers of 53 Mn and 59 Co atoms in the target were deduced via mass spectrometric measurements at PSI. Cold-neutron activation was carried out at the ICON beamline at PSI. Reactor activation was performed at the LVR-15 research reactor of Research Centrě Rež in a well-moderated neutron field of an outer reactor channel. The thermal-neutron capture cross section and the resonance integral were determined by the cadmium ratio method. The induced activities of 54 Mn and 60 Co were quantified by high-resolution γ-ray spectrometry. The obtained thermal-neutron capture cross section of 76.5 ± 1.4 b agrees well with previously reported results. The uncertainty of this value could be reduced by almost an order of magnitude with respect to older measurements and is on a level comparable to stable nuclides. The resonance integral of 43.1 ± 1.2 b was obtained for the real reactor spectrum with epithermal-spectrum shape factor α = 0.025.

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“…Small Angle Neutron Scatter(SANS), Ultra Small Angle Neutron Scattering(USANS) and Spin Echo Small Angle Neutron Scattering(SESAME) have been developed to probe large scale structures of various samples by measuring small angle scattering precisely. How to obtain more UCN is important in fundamental science, practical engineering, and industrial applications 11 12 13 14 15 16 , etc. Slowing down neutrons effectively is the key problem since the day when neutron was discovered.…”

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confidence: 99%

Rotational Effects of Nanoparticles for Cooling down Ultracold Neutrons

Sun

Gong

et al. 2017

Sci Rep

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Due to quantum coherence, nanoparticles have very large cross sections when scattering with very cold or Ultracold Neutrons (UCN). By calculating the scattering cross section quantum mechanically at first, then treating the nanoparticles as classical objects when including the rotational effects, we can derive the associated energy transfer. We find that rotational effects could play an important role in slowing down UCN. In consequence, the slowing down efficiency can be improved by as much as ~40%. Since thermalization of neutrons with the moderator requires typically hundreds of collisions between them, a ~40% increase of the efficiency per collision could have a significant effect. Other possible applications, such as neutrons scattering with nano shells and magnetic particles,and reducing the systematics induced by the geometric phase effect using nanoparticles in the neutron Electric Dipole Moment (nEDM), are also discussed in this paper.

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Nuclear reactions and physical models for neutron activation analysis

Cited by 19 publications

References 20 publications

Neutronic and burn‐up calculations of the ( ThO2‐UO2 ) pin cell benchmark using DRAGON5 and MCNP6 .2 codes with ENDF / B‐VIII .0 nuclear data library

Neutronic and burn‐up calculations of the ( ThO2‐UO2 ) pin cell benchmark using DRAGON5 and MCNP6 .2 codes with ENDF / B‐VIII .0 nuclear data library

Neutron capture cross section of Mn53 from irradiation with cold and reactor neutrons

Rotational Effects of Nanoparticles for Cooling down Ultracold Neutrons

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