Your search keyword '"Luka Snoj"' showing total 179 results

1. Impact of fuel temperature on nuclear core design calculations

Author

Dušan Čalič, Luka Snoj, and Marjan Kromar

Subjects

Effective temperature, Serpent, FINIX, Core design, Monte Carlo, Burnup, Nuclear engineering. Atomic power, TK9001-9401

Abstract

The operation of a nuclear power plant relies on precalculated nuclear design predictions based on core calculations of various reactor states. The fuel temperature is a crucial factor in determining the reactor fuel behavior, but assessing the temperature variation in a fuel pellet taking into account neutron transport is challenging. Detailed simulation of the temperature behavior within the fuel pellet can be obtained by coupling of Monte Carlo neutron transport codes with thermal-hydraulics solvers. However, this approach is not practical for standard nuclear design calculations, and computationally cheaper and faster methods must be used. In nuclear core simulators, a concept of a single ''effective temperature'' that yields the same neutron response as in the case of the actual temperature shape is mainly applied. This paper evaluates various fuel temperature models used in nuclear core simulation calculations, ultimately recommending a new effective temperature model that considers the burnup correction.

Published

2024

2. JSI TRIGA fuel rod reactivity worth experiments for validation of Serpent-2 and RAPID fuel burnup calculations

Author

Anže Pungerčič, Alireza Haghighat, and Luka Snoj

Subjects

Burnup calculation, Experimental validation, TRIGA reactor, Reactivity measurements, Fission matrix, Nuclear engineering. Atomic power, TK9001-9401

Abstract

Reactivity worth of fuel rods at the JSI TRIGA research reactor was measured. Differently burned fuel rods were chosen to validate fuel burnup calculations. Two methods of measuring reactivity worth of fuel rods are used, traditional method is compared to newly introduced method using fuel rods swapping. Connection between both methods is described theoretically and the theory is validated experimentally. Fuel rod worth calculated using the newly introduced fuel rod swap method was within 1σ of worth measured using the traditional method. In addition to the recently performed experiments, weekly measurements of reactor core reactivity throughout the operational history are used for validation. The measured data were used to validate the fuel burnup and core criticality calculations. Fuel burnup calculations are performed using three different computer codes: the deterministic TRIGLAV, the Monte Carlo Serpent-2, and the hybrid RAPID. Great agreement was observed for Serpent-2 and RAPID by simulating fuel rod worth and its burnup, indicating that the fuel burnup and criticality calculations are accurate and that reactivity changes due to small burnup differences on the order of 10 pcm can be accurately simulated. In addition it was shown using ex-core detectors and large fission chamber that detector response changes due to fuel swapping are evident for fuel rod burnup differences of 20 MWd/kg. Fuel burnup calculations were further validated on excess reactivity measurements for three mixed TRIGA cores. The calculated burnup reactivity coefficient ΔρBU using Serpent-2 and RAPID was within 1σ of the measurements, showing both codes are capable of calculating burnup for different TRIGA fuel types.

Published

2024

3. Analysis of fluctuations in ex-core neutron detector signal in Krško NPP during an earthquake

Author

Tanja Goričanec, Andrej Kavčič, Marjan Kromar, and Luka Snoj

Subjects

Pressurized water reactor, Krško Nuclear Power Plant, Monte Carlo neutron transport, Earthquake, Ex-core neutron detector, MCNP, Nuclear engineering. Atomic power, TK9001-9401

Abstract

During an earthquake on December 29th 2020, the Krško NPP automatically shutdown due to the trigger of the negative neutron flux rate signal on the power range nuclear instrumentation. From the time course of the detector signal, it can be concluded that the fluctuation in the detector signal may have been caused by the mechanical movement of the ex-core neutron detectors or the pressure vessel components rather than the actual change in reactor power. The objective of the analysis was to evaluate the sensitivity of the neutron flux at the ex-core detector position, if the detector is moved in the radial or axial direction. In addition, the effect of the core barrel movement and core inside the baffle movement in the radial direction were analysed. The analysis is complemented by the calculation of the thermal and total neutron flux gradient in radial, axial and azimuthal directions. The Monte Carlo particle transport code MCNP was used to study the changes in the response of the ex-core detector for the above-mentioned scenarios. Power and intermediate-range detectors were analysed separately, because they are designed differently, positioned at different locations, and have different response characteristics. It was found that the movement of the power range ex-core detector has a negligible effect on the value of the thermal neutron flux in the active part of the detector. However, the radial movement of the intermediate-range detector by 5 cm results in 7%–8% change in the thermal neutron flux in the active part of the intermediate-range detector. The analysis continued with an evaluation of the effects of moving the entire core barrel on the ex-core detector response. It was estimated that the 2 mm core barrel radial oscillation results in ∼4% deviation in the power and intermediate-range detector signal. The movement of the reactor core inside baffle can contribute ∼6% deviation in the ex-core neutron detector signal. The analysis showed that the mechanical movement of ex-core neutron detectors cannot explain the fluctuations in the ex-core detector signal. However, combined core barrel and reactor core inside baffle oscillations could be a probable reason for the observed fluctuations in the ex-core detector signal during an earthquake.

Published

2024

4. Evaluation of cross sections for fast ion reactions with beryllium in helium and hydrogen fusion plasmas

Author

Andrej Žohar, Andrej Trkov, Anders Hjalmarsson, Žiga Štancar, Gašper Žerovnik, Jan Malec, and Luka Snoj

Subjects

cross section, beryllium, FENDL, uncertainty, evaluation, Nuclear and particle physics. Atomic energy. Radioactivity, QC770-798

Abstract

To computationally support hydrogen and helium plasma discharges in the early stages of tokamak operation and to support the commissioning of the neutron detectors during these operational phases, creation of a realistic neutron and gamma ray particle source for Monte Carlo simulations will be needed. One of the most important parts of creating the particle source is calculating the reaction rates of the particle-emitting reactions to determine the emission profile in the plasma and the energy spectra of the emitted particles. In this paper the analysis and evaluation of cross sections for important neutron-emitting reactions, namely, ^9 Be(p,n γ ) ^9 B, ^9 Be( ^3 He,n γ ) ^11 C, and charged-particle emission reactions ^9 Be(p,d)2 α and ^9 Be(p, α ) ^6 Li that cause neutron emission in the next step of interactions are presented. The reaction cross sections were evaluated based on experimental measurements and empirical models describing the interaction of two charged particles. Evaluation of the associated uncertainties was also performed. The main goal of the work is to propose the newly evaluated cross sections for inclusion in the FENDL nuclear data library, thus making the cross section available to other researchers studying the above listed reactions.

Published

2024

5. An overview of power reactor kinetics and control in load-following operation modes

Author

Gašper Žerovnik, Dušan Čalič, Samo Gerkšič, Marjan Kromar, Jan Malec, Anže Mihelčič, Andrej Trkov, and Luka Snoj

Subjects

load-following, reactor kinetics, reactor control, reference scenarios, reactivity feedback, General Works

Abstract

Previous work done on reactor kinetics and control in load-following operation modes available in open literature is reviewed. The analysis is focused on, however not limited to pressurized water reactors. Different approximations of the time-dependent neutron transport problem as well as different control algorithms are described in detail and compared. Due to lack of published information the majority of the comparisons was done on qualitative level. In order to facilitate future testing and intercomparisons of models and algorithms, two so-called reference scenarios with time-dependent power demand are defined: a scenario to test the limitations of the load-following capabilities of the nuclear facilities and a second, quasi-realistic scenario.

Published

2023

6. Determination of neutron flux redistribution factors for a typical pressurized water reactor ex-core measurements using Monte Carlo technique

Author

Tanja Goričanec, Bor Kos, Klemen Ambrožič, Andrej Trkov, Luka Snoj, and Marjan Kromar

Subjects

MCNP, ADVANTG, pressurized water reactor, Monte Carlo neutron transport, control rod, neutron flux redistribution factor, General Works

Abstract

In a typical pressurized water reactor, neutron detectors located outside the reactor core monitor reactor power. In addition, they are also used to measure the reactivity of the control rods. A novel approach to calculate the ex-core neutron detector response in a typical pressurized water reactor using the Monte Carlo technique is presented. A detailed ex-core model of the Krško nuclear power plant was developed using the Monte Carlo neutron transport code MCNP. Due to the location of the ex-core neutron detectors, the hybrid code ADVANTG is used to generate variance reduction parameters to accelerte the convergence of the results outside the reactor core. To use ADVANTG, the fixed neutron source had to be reconstructed from the criticality core calculation. This paper presents the sensitivity analysis of the response of the ex-core detectors to the neutron data libraries used, the description of the fixed neutron source and the ADVANTG parameters. It was found that a pin-wise description of the neutron source for at least two rows of fuel assemblies at the core periphery is necessary for accurate results. Our results show the importance of a correct description of the prompt neutron spectra in the high energy region and the impact this has on the response of the ex-core detectors. The method in which the prompt neutron fission spectra for important fission nuclides are weighted by the calculated reaction rates has been shown to be the best approximation, with deviations from the reference calculation within statistical uncertainty. The effect of nuclear data libraries on the response of the ex-core detector was investigated, and the difference between the ENDF/B-VII.0 and the ENDF/B-VIII.0 nuclear data libraries was ∼11%. When the deficient evaluation of the 56Fe isotope included in the ENDF/B-VIII.0 nuclear data library was replaced by the improved evaluation from the IAEA INDEN project, the differences decreased to ∼3.7%. In addition, neutron flux redistributions due to control rod movement were investigated and flux redistribution factors were updated using Monte Carlo particle transport methods. The reaction rate redistribution factors obtained with methods presented in this paper are within 1% agreement with the currently used factors.

Published

2023

7. Applicability of the Krško nuclear power plant core Monte Carlo model for the determination of the neutron source term

Author

Tanja Goričanec, Žiga Štancar, Domen Kotnik, Luka Snoj, and Marjan Kromar

Subjects

Pressurized water reactor, Krško nuclear power plant, Monte Carlo neutron transport, MCNP, CORD-2, In-core neutron detector, Nuclear engineering. Atomic power, TK9001-9401

Abstract

A detailed geometrical model of a Krško reactor core was developed using a Monte Carlo neutron transport code MCNP. The main goal of developing an MCNP core model is for it to be used in future research focused on ex-core calculations. A script called McCord was developed to generate MCNP input for an arbitrary fuel cycle configuration from the diffusion based core design package CORD-2, taking advantage of already available material and temperature data obtained in the nuclear core design process. The core model was used to calculate 3D power density profile inside the core. The applicability of the calculated power density distributions was tested by comparison to the CORD-2 calculations, which is regularly used for the nuclear core design calculation verification of the Krško core. For the hot zero power and hot full power states differences between MCNP and CORD-2 in the radial power density profile were

Published

2021

8. Nuclear-driven production of renewable fuel additives from waste organics

Author

Arran George Plant, Bor Kos, Anže Jazbec, Luka Snoj, Vesna Najdanovic-Visak, and Malcolm John Joyce

Subjects

Chemistry, QD1-999

Abstract

A current trend towards the sustainable production of valuable chemicals consists in coupling nuclear energy with the chemical industry. Here, the authors propose to use γ radiation to transform glycerol (a waste product of biorefineries) into high-value solketal.

Published

2021

9. Use of Gaussian process regression for radiation mapping of a nuclear reactor with a mobile robot

Author

Andrew West, Ioannis Tsitsimpelis, Mauro Licata, Anz̆e Jazbec, Luka Snoj, Malcolm J. Joyce, and Barry Lennox

Subjects

Medicine, Science

Abstract

Abstract Collection and interpolation of radiation observations is of vital importance to support routine operations in the nuclear sector globally, as well as for completing surveys during crisis response. To reduce exposure to ionizing radiation that human workers can be subjected to during such surveys, there is a strong desire to utilise robotic systems. Previous approaches to interpolate measurements taken from nuclear facilities to reconstruct radiological maps of an environment cannot be applied accurately to data collected from a robotic survey as they are unable to cope well with irregularly spaced, noisy, low count data. In this work, a novel approach to interpolating radiation measurements collected from a robot is proposed that overcomes the problems associated with sparse and noisy measurements. The proposed method integrates an appropriate kernel, benchmarked against the radiation transport code MCNP6, into the Gaussian Process Regression technique. The suitability of the proposed technique is demonstrated through its application to data collected from a bespoke robotic system used to conduct a survey of the Joz̆ef Stefan Institute TRIGA Mark II nuclear reactor during steady state operation, where it is shown to successfully reconstruct gamma dosimetry estimates in the reactor hall and aid in identifying sources of ionizing radiation.

Published

2021

10. Influence of neutron and gamma irradiation on the electrocaloric properties of Mn-doped 0.9Pb(Mg1/3Nb2/3)O3–0.1PbTiO3 ceramics

Author

Ankita Sarkar, Matej Šadl, Anže Jazbec, Luka Snoj, Silvo Drnovšek, Tadej Rojac, Geoff L Brennecka, Hana Uršič, and Barbara Malič

Subjects

neutron radiation, electrocaloric, PMN–10PT, Mn-doped PMN–10PT, ferroelectrics, relaxor, Production of electric energy or power. Powerplants. Central stations, TK1001-1841, Renewable energy sources, TJ807-830

Abstract

The influence of neutron and gamma irradiation on the low- and high-field dielectric and electrocaloric (EC) properties of Mn-doped 0.9Pb(Mg _1/3 Nb _2/3 )O _3 –0.1PbTiO _3 (PMN–10PT) ceramic is studied. Upon exposure to neutron fluences of up to 10 ^17 cm ^−2 and gamma-ray doses of up to 1200 kGy the Mn-doped PMN–10PT exhibits a lower saturated polarization, increased internal bias field and reduced EC temperature change. In comparison, the respective properties of the undoped PMN–10PT remain almost unchanged upon exposure to neutrons and gamma rays. In Mn-doped PMN–10PT, the acceptor-oxygen vacancy defect complexes, introduced via doping, contribute to the lowering of the threshold radiation dose that the material survives without noticeable changes in properties. Radiation-induced degradation of the EC response of Mn-doped PMN–10PT can be partially healed by annealing at 450 °C. The study provides guidance for designing EC ceramic materials for solid-state cooling applications in environments of high ionizing radiation, such as the medical field or space technologies.

Published

2023

11. Computational design and characterization of a subcritical reactor assembly with TRIGA fuel

Author

Alvie Asuncion-Astronomo, Žiga Štancar, Tanja Goričanec, and Luka Snoj

Subjects

Nuclear engineering. Atomic power, TK9001-9401

Abstract

The TRIGA fuel of the Philippine Research Reactor-1 (PRR-1) will be used in a subcritical reactor assembly (SRA) to strengthen and advance nuclear science and engineering expertise in the Philippines. SRA offers a versatile and safe training and research facility since it can produce neutrons through nuclear fission reaction without achieving criticality. In this work, we used a geometrically detailed model of the PRR-1 TRIGA fuel to design a subcritical reactor assembly and calculate physical parameters of different fuel configurations. Based on extensive neutron transport simulations an SRA configuration is proposed, comprising 44 TRIGA fuel rods arranged in a 7 × 7 square lattice. This configuration is found to have a maximum keff value of 0.95001±0.00009 at 4 cm pitch. The SRA is characterized by calculating the 3-dimensional neutron flux distribution and neutron spectrum. The effective delayed neutron fraction and mean neutron generation time of the system are calculated to be 748pcm±7pcm and 41μs, respectively. Results obtained from this work will be the basis of the core design for the subcritical reactor facility that will be established in the Philippines. Keywords: Nuclear reactor, Subcritical assembly, TRIGA fuel, MCNP

Published

2019

12. M-Center in Neutron-Irradiated 4H-SiC

Author

Ivana Capan, Tomislav Brodar, Takahiro Makino, Vladimir Radulovic, and Luka Snoj

Subjects

defects, 4H-SiC, DLTS, neutrons, Crystallography, QD901-999

Abstract

We report on the metastable defects introduced in the n-type 4H-SiC material by epithermal and fast neutron irradiation. The epithermal and fast neutron irradiation defects in 4H-SiC are much less explored compared to electron or proton irradiation-induced defects. In addition to the carbon vacancy (Vc), silicon vacancy (Vsi) and carbon antisite-carbon vacancy (CAV) complex, the neutron irradiation has introduced four deep-level defects, all arising from the metastable defect, the M-center. The metastable deep-level defects were investigated by deep level transient spectroscopy (DLTS), high-resolution Laplace DLTS (L-DLTS) and isothermal DLTS. The existence of the fourth deep-level defect, M4, recently observed in ion-implanted 4H-SiC, has been additionally confirmed in neutron-irradiated samples. The isothermal DLTS technique has been proven as a useful tool for studying the metastable defects.

Published

2021

13. Depth Profile Analysis of Deep Level Defects in 4H-SiC Introduced by Radiation

Author

Tomislav Brodar, Luka Bakrač, Ivana Capan, Takeshi Ohshima, Luka Snoj, Vladimir Radulović, and Željko Pastuović

Subjects

silicon carbide, defects, ion implantation, DLTS, neutron radiation, Crystallography, QD901-999

Abstract

Deep level defects created by implantation of light-helium and medium heavy carbon ions in the single ion regime and neutron irradiation in n-type 4H-SiC are characterized by the DLTS technique. Two deep levels with energies 0.4 eV (EH1) and 0.7 eV (EH3) below the conduction band minimum are created in either ion implanted and neutron irradiated material beside carbon vacancies (Z1/2). In our study, we analyze components of EH1 and EH3 deep levels based on their concentration depth profiles, in addition to (−3/=) and (=/−) transition levels of silicon vacancy. A higher EH3 deep level concentration compared to the EH1 deep level concentration and a slight shift of the EH3 concentration depth profile to larger depths indicate that an additional deep level contributes to the DLTS signal of the EH3 deep level, most probably the defect complex involving interstitials. We report on the introduction of metastable M-center by light/medium heavy ion implantation and neutron irradiation, previously reported in cases of proton and electron irradiation. Contribution of M-center to the EH1 concentration profile is presented.

Published

2020

14. Geografsko vrednotenje degradiranih območij v izbranih statističnih regijah

Author

Anja Cvahte and Luka Snoj

Subjects

degradirana območja, trajnostni razvoj, varovana območja, pokrajin-skoekološki tipi, Geography (General), G1-922

Abstract

Degradirana območja so neustrezno izkoriščeni deli pokrajine, ki s primerno ureditvijo in upravljanjem predstavljajo potencial za trajnostno rabo. Enotna, celovita in ažurna evidenca degradiranih območij je le začetna faza pri doseganju tega cilja. V prispevku je predstavljena identifikacija, inventarizacija ter geografsko vrednotenje degradiranih območij v Gorenjski, Osrednjeslovenski, Zasavski in Spodnjeposavski statistični regiji ter v statistični regiji Jugovzhodna Slovenija.

Published

2011

15. Modeling of γ field around irradiated TRIGA fuel elements by R2S method

Author

Klemen Ambrožič and Luka Snoj

Subjects

Physics, QC1-999

Abstract

The JSI TRIGA reactor has several irradiation facilities with well characterized neutron fields. The characterization was performed by measurements and by utilizing Monte Carlo particle transport computational methods. Because of this, JSI TRIGA has become a reference center for neutron irradiation of detectors for ATLAS experiment (CERN). Thorough γ characterization of the reactor is however yet to be performed. Current Monte Carlo particle transport code only account for the prompt generation of neutron induced γ rays, which have been characterized, but are neglecting the time dependent delayed part, which may in some cases amount to more then 30% of total γ flux in an operation reactor, and is the only source of γ-rays after reactor shutdown. Several common approaches of modeling delayed -rays , namely D1S and R2S exist. In this paper an in-house developed R2S method code is described, coupling a Monte Carlo particle transport code MCNP6 and neutron activation code FISPACT-II, with intermediate steps performed by custom Python scripts. An example of its capabilities is presented in terms of evaluation of utilization of JSI TRIGA nuclear fuel as a viable γ-ray source. In the model, fresh nuclear fuel is considered and a silicon pipe sample is modeled in. Fuel activities, dose and kerma rates on the sample, as well as emitted γ-ray spectra and isotopic contribution to the contact dose are calculated and presented.

Published

2017

16. On the development of radiation tolerant surveillance camera from consumer-grade components

Author

Klemen Ambrožič, Luka Snoj, Lars Öhlin, Jan Gunnarsson, and Niklas Barringer

Subjects

Physics, QC1-999

Abstract

In this paper an overview on the process of designing a radiation tolerant surveillance camera from consumer grade components and commercially available particle shielding materials is given. This involves utilization of Monte-Carlo particle transport code MCNP6 and ENDF/B-VII.0 nuclear data libraries, as well as testing the physical electrical systems against γ radiation, utilizing JSI TRIGA mk. II fuel elements as a γ-ray sources. A new, aluminum, 20 cm × 20 cm × 30 cm irradiation facility with electrical power and signal wire guide-tube to the reactor platform, was designed and constructed and used for irradiation of large electronic and optical components assemblies with activated fuel elements. Electronic components to be used in the camera were tested against γ-radiation in an independent manner, to determine their radiation tolerance. Several camera designs were proposed and simulated using MCNP, to determine incident particle and dose attenuation factors. Data obtained from the measurements and MCNP simulations will be used to finalize the design of 3 surveillance camera models, with different radiation tolerances.

Published

2017

17. High radiation tolerance of electrocaloric (1-x)Pb(Mg1/3Nb2/3)O3–xPbTiO3

Author

Hana Uršič, Uroš Prah, Tadej Rojac, Anže Jazbec, Luka Snoj, Silvo Drnovšek, Andraž Bradeško, Anja Mirjanić, Marko Vrabelj, and Barbara Malič

Subjects

Materials Chemistry, Ceramics and Composites

Published

2022

18. Thermal Simulations of a New SiC Detector Design for Neutron Measurements in JSI Nuclear Research Reactor

Author

Valentin Valero, Laurent Ottaviani, Abdallah Lyoussi, Vladimir Radulović, Luka Snoj, Adrien Volte, Michel Carette, and Christelle Reynard Carette

Subjects

Mechanics of Materials, Mechanical Engineering, General Materials Science, Condensed Matter Physics

Abstract

Today, to respond to the increase of development of accurate, precise and relevant experiments in nuclear research reactors and tokamaks with their severe and intense operating conditions, there is a major need of innovative sensors that can accurately measure key parameters such as neutron and photon fluxes or nuclear heating rates. Thus, innovation in the field of nuclear instrumentation and measurements is a privileged research topic. It is crucial to develop optimized devices for accurate on-line in-core measurements, and scientific/technological requirements for various applications such as ageing of materials, safety applications, beam monitoring or nuclear physics. Nowadays, more and more semiconductors are used as sensor materials in nuclear instrumentation to measure various kinds of nuclear radiations. Silicon Carbide (SiC) is among them. In fact, SiC detectors could be used for the on-line measurement of key quantities such as neutron (thermal and fast) and photon fluxes. One main challenge is to enlarge the measurement range of this detector type. The work presented in this paper deals with this aim. Firstly, an introduction dedicated to the use of SiC versus other wide bandgap semiconductors and the characteristics of the studied sensor is shown. Secondly, this paper presents 3D numerical results obtained with a parametrical thermal study of the SiC detector using COMSOL Multiphysics code for a nuclear heating range corresponding to TRIGA nuclear research reactor conditions (integral neutron flux ~2.0 x1013 n·cm‑2·s-1 leading to a nuclear heating rate of 0.25 W·g-1 in Tungsten). The main objective is to adapt and optimize the design and the housing of the detector by determining its temperature field for different configurations. The influence of various parameters is presented such as that of the housing material nature, the gas nature around the diode, the gas-gap height and the housing thickness.

Published

2022

19. Radiation Response of Large-Area 4H-SiC Schottky Barrier Diodes

Author

Robert Bernat, Tihomir Knežević, Vladimir Radulović, Luka Snoj, Takahiro Makino, Takeshi Ohshima, and Ivana Capan

Subjects

General Materials Science, silicon carbide, radiation detector, neutron radiation, nuclear reactor, alpha particles

Abstract

We report on the effects of large-area 4H-SiC Schottky barrier diodes on the radiation response to ionizing particles. Two different diode areas were compared: 1 mm × 1 mm and 5 mm × 5 mm. 6LiF and 10B4C films, which were placed on top of the diodes, were used as thermal neutron converters. We achieved a thermal neutron efficiency of 5.02% with a 6LiF thermal neutron converter, which is one of the highest efficiencies reported to date. In addition, a temperature-dependent radiation response to alpha particles was presented. Neutron irradiations were performed in a JSI TRIGA dry chamber and an Am-241 wide-area alpha source was used for testing the alpha response of the 4H-SiC Schottky barrier diodes.

Published

2023

20. Applicability of the Krško nuclear power plant core Monte Carlo model for the determination of the neutron source term

Author

Domen Kotnik, Žiga Štancar, Marjan Kromar, Luka Snoj, and Tanja Goričanec

Subjects

Physics, Neutron transport, Nuclear engineering, Monte Carlo neutron transport, Monte Carlo method, TK9001-9401, CORD-2, Krško nuclear power plant, law.invention, Core (optical fiber), Nuclear Energy and Engineering, Nuclear reactor core, law, Nuclear power plant, In-core neutron detector, MCNP, Neutron source, Pressurized water reactor, Nuclear engineering. Atomic power, Core model, Power density

Abstract

A detailed geometrical model of a Krško reactor core was developed using a Monte Carlo neutron transport code MCNP. The main goal of developing an MCNP core model is for it to be used in future research focused on ex-core calculations. A script called McCord was developed to generate MCNP input for an arbitrary fuel cycle configuration from the diffusion based core design package CORD-2, taking advantage of already available material and temperature data obtained in the nuclear core design process. The core model was used to calculate 3D power density profile inside the core. The applicability of the calculated power density distributions was tested by comparison to the CORD-2 calculations, which is regularly used for the nuclear core design calculation verification of the Krško core. For the hot zero power and hot full power states differences between MCNP and CORD-2 in the radial power density profile were

Published

2021

21. Design optimization of the closed-water activation loop at the JSI irradiation facility

Author

Domen Kotnik, Anil Kumar Basavaraj, Luka Snoj, and Igor Lengar

Subjects

Nuclear Energy and Engineering, Mechanical Engineering, General Materials Science, Civil and Structural Engineering

Published

2023

22. Verification and Validation of RAPID Formulations and Algorithms Based on Dosimetry Measurements at the JSI TRIGA Mark-II Reactor

Author

Valerio Mascolino, Luka Snoj, and Alireza Haghighat

Subjects

Nuclear Energy and Engineering, Computer science, Detector response function, Dosimetry, Experimental validation, Nonlinear Sciences::Cellular Automata and Lattice Gases, Algorithm, TRIGA, Verification and validation

Abstract

In this paper, detailed verification and experimental validation of the formulations and algorithms of the Multi-stage Response-function Transport (MRT)–based Real-time Analysis for Particle-transp...

Published

2021

23. Benchmark Evaluation of one Dimensional Array of HEU Moderated and Reflected by Lucite [Poster]

Author

Igor Lengar, Domen Kotnik, Luka Snoj, Jesson Hutchinson, Rene Sanchez, and Travis Grove

Published

2022

24. The Application of Vibrational Spectroscopy in the Analysis of Ultra-High Molecular Weight Polyethylene for Knee and Hip Prosthetics

Author

Matic. J. Grdadolnik, Arne K. Marušič, Monika Jenko, Luka Snoj, Alenka Mozer, Drago Dolinar, Urban Nova, Matic. J. Grdadolnik, Arne K. Marušič, Monika Jenko, Luka Snoj, Alenka Mozer, Drago Dolinar, and Urban Nova

Abstract

We systematically used infrared (IR) and Raman spectroscopy to study the structure of unprocessed and perturbed UHMWPE by ?-irradiation. We tested the proposed methods on selected polymer samples with known structure. We used vibrational spectroscopy to analyse the chemical structure of two different types of UHMWPE with different molecular weight and density under the trade names GUR 1020 and GUR 1050. The samples were exposed to four different doses of g-irradiation, which induces the cross-linking and oxidation of polyethylene chains. The showed results proved that vibration spectroscopy can be a fast, efficient, non-destructive and simple tool to characterize the oxidation and degree of crystallinity of UHMWPE, while the accuracy of determining the degree of cross-linking was omitted by the process of oxidation and band overlapping.

Published

2022

25. Distinguishing the EH1 and S1 defects in n-type 4H-SiC by Laplace DLTS

Author

Tihomir Knežević, Tomislav Brodar, Vladimir Radulović, Luka Snoj, Takahiro Makino, and Ivana Capan

Subjects

Condensed Matter - Materials Science, General Engineering, General Physics and Astronomy, Materials Science (cond-mat.mtrl-sci), FOS: Physical sciences

Abstract

We report on the low-energy electron and fast neutron irradiated 4H-SiC studied by deep-level transient spectroscopy (DLTS) and Laplace DLTS. Irradiations introduced two defects, E c −0.4 eV and E c −0.7 eV. They were previously assigned to carbon interstitial (Ci) labeled as EH1/3 and silicon-vacancy (V Si) labeled as S1/2, for the low-energy electron and fast neutron irradiation, respectively. This work demonstrates how Laplace DLTS can be used as a useful tool for distinguishing the EH1 and S1 defects. We show that EH1 consists of a single emission line arising from the Ci(h), while S1 has two emission lines arising from the V Si(h) and V Si(k) lattice sites.

Published

2022

26. Use of Gaussian process regression for radiation mapping of a nuclear reactor with a mobile robot

Author

Ioannis Tsitsimpelis, Barry Lennox, Anz E Jazbec, Andrew West, Mauro Licata, Malcolm J. Joyce, and Luka Snoj

Subjects

Computer science, Science, Real-time computing, 02 engineering and technology, 030204 cardiovascular system & hematology, Article, law.invention, 03 medical and health sciences, 0302 clinical medicine, law, Kriging, 0202 electrical engineering, electronic engineering, information engineering, Dosimetry, Multidisciplinary, Nuclear energy, Mobile robot, Nuclear reactor, Electrical and electronic engineering, Kernel (statistics), Medicine, Robot, 020201 artificial intelligence & image processing, Count data, Interpolation

Abstract

Collection and interpolation of radiation observations is of vital importance to support routine operations in the nuclear sector globally, as well as for completing surveys during crisis response. To reduce exposure to ionizing radiation that human workers can be subjected to during such surveys, there is a strong desire to utilise robotic systems. Previous approaches to interpolate measurements taken from nuclear facilities to reconstruct radiological maps of an environment cannot be applied accurately to data collected from a robotic survey as they are unable to cope well with irregularly spaced, noisy, low count data. In this work, a novel approach to interpolating radiation measurements collected from a robot is proposed that overcomes the problems associated with sparse and noisy measurements. The proposed method integrates an appropriate kernel, benchmarked against the radiation transport code MCNP6, into the Gaussian Process Regression technique. The suitability of the proposed technique is demonstrated through its application to data collected from a bespoke robotic system used to conduct a survey of the Joz̆ef Stefan Institute TRIGA Mark II nuclear reactor during steady state operation, where it is shown to successfully reconstruct gamma dosimetry estimates in the reactor hall and aid in identifying sources of ionizing radiation.

Published

2021

27. Neutron resonance transmission analysis of cylindrical samples used for reactivity worth measurements

Author

Gilles Noguere, Luka Snoj, Benoit Geslot, Stefan Kopecky, Pierre Leconte, Jan Heyse, C. Paradela, Peter Schillebeeckx, and L. Šalamon

Subjects

Materials science, QC1-999, 020209 energy, Health, Toxicology and Mutagenesis, Neutron resonance, Analytical chemistry, chemistry.chemical_element, 02 engineering and technology, Tungsten, 010403 inorganic & nuclear chemistry, 01 natural sciences, Analytical Chemistry, 0103 physical sciences, 0202 electrical engineering, electronic engineering, information engineering, Radiology, Nuclear Medicine and imaging, Reactivity (chemistry), Nuclide, Spectroscopy, 010308 nuclear & particles physics, Physics, Radiochemistry, Public Health, Environmental and Occupational Health, Pollution, 0104 chemical sciences, Nuclear Energy and Engineering, chemistry

Abstract

A characterisation of cylindrical samples by Neutron Resonance Transmission Analysis (NRTA) at the GELINA facility of JRC Geel (Belgium) is presented. The samples were designed and produced for reactivity worth measurements in the MINERVE reactor of CEA Cadarache (France). NRTA was applied to determine the nuclide composition of UO2, Al2O3 and liquid samples that were doped with silver. The volume number densities of 238U, 107Ag and 109Ag obtained by NRTA are within 2 % fully consistent with the values that are quoted by the manufacturer. In addition, the NRTA data reveal a tungsten contamination which is not reported by the provider. It is shown that such a contamination contributes by up to 5.7 % to the reactivity worth.

Published

2019

28. 107Ag and 109Ag resonance parameters for neutron induced reactions below 1 keV

Author

Stefan Kopecky, L. Šalamon, Peter Schillebeeckx, Gilles Noguere, J. Heyse, Luka Snoj, C. Paradela, Pierre Leconte, and Benoit Geslot

Subjects

Physics, Nuclear physics, Nuclear and High Energy Physics, Neutron resonance, Neutron cross section, Resonance, Neutron, Neutron transmission, Radiation, Instrumentation, Spectral line, Shape analysis (digital geometry)

Abstract

Neutron transmission and capture measurements have been performed at the time-of-flight (TOF) facility GELINA of the EC-JRC-Geel, using metallic discs of natural silver with different thicknesses. Resonances of neutron interactions with 107Ag and 109Ag were analysed in the energy region below 1 keV applying the Reich-Moore approximation of the R-Matrix theory. Discrepancies between the experimental data and calculations based on the neutron resonance parameters recommended in the main neutron cross section libraries (JEFF, ENDF/B, JENDL) were observed. Improved resonance parameters were determined by a resonance shape analysis using the REFIT code. The resonance energy, neutron (Γn) and radiation (Γγ) width were adjusted in a simultaneous fit to transmission and capture yield spectra below 100 eV. Above 100 eV fixed average radiation widths ( Γ γ 107 =140 meV, Γ γ 109 = 130 meV) were used and the neutron width Γn was adjusted to only the capture yield data. Capture resonance integral I0 were calculated from the parameters derived in this work (I0,107 = 101.20 b, I0,109 = 1515.24 b) and compared with those calculated using the cross sections recommended in the main libraries. Discrepancies in I0 for 107Ag are mainly due to difference in the parameters of the resonances at 16.4 eV, 41.6 eV, 173.9 eV and 202.8 eV. In case of 109Ag differences are mainly due to the difference in parameters of the resonance at 5.2 eV.

Published

2019

29. Computational design and characterization of a subcritical reactor assembly with TRIGA fuel

Author

Žiga Štancar, Alvie Asuncion-Astronomo, Luka Snoj, and Tanja Goričanec

Subjects

Neutron transport, Materials science, 020209 energy, Nuclear engineering, 02 engineering and technology, 7. Clean energy, Subcritical reactor, lcsh:TK9001-9401, 030218 nuclear medicine & medical imaging, TRIGA, 03 medical and health sciences, 0302 clinical medicine, Nuclear Energy and Engineering, Criticality, Neutron flux, Nuclear fission, 0202 electrical engineering, electronic engineering, information engineering, lcsh:Nuclear engineering. Atomic power, Neutron, Physics::Chemical Physics, Nuclear Experiment, Delayed neutron

Abstract

The TRIGA fuel of the Philippine Research Reactor-1 (PRR-1) will be used in a subcritical reactor assembly (SRA) to strengthen and advance nuclear science and engineering expertise in the Philippines. SRA offers a versatile and safe training and research facility since it can produce neutrons through nuclear fission reaction without achieving criticality. In this work, we used a geometrically detailed model of the PRR-1 TRIGA fuel to design a subcritical reactor assembly and calculate physical parameters of different fuel configurations. Based on extensive neutron transport simulations an SRA configuration is proposed, comprising 44 TRIGA fuel rods arranged in a 7 × 7 square lattice. This configuration is found to have a maximum k e f f value of 0.95001 ± 0.00009 at 4 cm pitch. The SRA is characterized by calculating the 3-dimensional neutron flux distribution and neutron spectrum. The effective delayed neutron fraction and mean neutron generation time of the system are calculated to be 748 pcm ± 7 pcm and 41 μs , respectively. Results obtained from this work will be the basis of the core design for the subcritical reactor facility that will be established in the Philippines.

Published

2019

30. The dose accumulation and the impact of deformable image registration on dose reporting parameters in a moving patient undergoing proton radiotherapy

Author

Gasper Razdevsek, Urban Simoncic, Luka Snoj, and Andrej Studen

Subjects

Lung Neoplasms, Oncology, Radiotherapy Planning, Computer-Assisted, Image Processing, Computer-Assisted, Humans, Radiology, Nuclear Medicine and imaging, Radiotherapy Dosage, Protons

Abstract

Introduction Potential changes in patient anatomy during proton radiotherapy may lead to a deviation of the delivered dose. A dose estimate can be computed through a deformable image registration (DIR) driven dose accumulation. The present study evaluates the accumulated dose uncertainties in a patient subject to an inadvertent breathing associated motion. Materials and methods A virtual lung tumour was inserted into a pair of single participant landmark annotated computed tomography images depicting opposite breathing phases, with the deep inspiration breath-hold the planning reference and the exhale the off-reference geometry. A novel Monte Carlo N-Particle, Version 6 (MCNP6) dose engine was developed, validated and used in treatment plan optimization. Three DIR methods were compared and used to transfer the exhale simulated dose to the reference geometry. Dose conformity and homogeneity measures from International Committee on Radioactivity Units and Measurements (ICRU) reports 78 and 83 were evaluated on simulated dose distributions registered with different DIR algorithms. Results The MCNP6 dose engine handled patient-like geometries in reasonable dose calculation times. All registration methods were able to align image associated landmarks to distances, comparable to voxel sizes. A moderate deterioration of ICRU measures was encountered in comparing doses in on and off-reference anatomy. There were statistically significant DIR driven differences in ICRU measures, particularly a 10% difference in the relative D98% for planning tumour volume and in the 3 mm/3% gamma passing rate. Conclusions T he dose accumulation over two anatomies resulted in a DIR driven uncertainty, important in reporting the associated ICRU measures for quality assurance.

Published

2021

31. Experimental validation of an integrated modelling approach to neutron emission studies at JET

Author

Gabor Szepesi, Ye. O. Kazakov, H. Weisen, Sean Conroy, Teddy Craciunescu, P. Sirén, Vladimir Radulović, L. Garzotti, Andrej Žohar, Jet Contributors, Luka Snoj, M. Dreval, Massimo Nocente, Jacob Eriksson, M. Gorelenkova, E. Militello-Asp, Žiga Štancar, Y. Baranov, Vasily Kiptily, Z. Ghani, K. Kirov, Stancar, Z, Ghani, Z, Eriksson, J, Zohar, A, Conroy, S, Kazakov, Y, Craciunescu, T, Kirov, K, Nocente, M, Garzotti, L, Radulovic, V, Siren, P, Kiptily, V, Baranov, Y, Szepesi, G, Dreval, M, Gorelenkova, M, Weisen, H, Militello-Asp, E, and Snoj, L

Subjects

neutron diagnostics, Nuclear and High Energy Physics, TRANSP, Neutron emission, Astrophysics::High Energy Astrophysical Phenomena, Nuclear Theory, neutron activation, 01 natural sciences, 010305 fluids & plasmas, Nuclear physics, Physics::Plasma Physics, generation, 0103 physical sciences, diagnostics, fast ion, fast ions, 010306 general physics, Nuclear Experiment, tokamak, Physics, Jet (fluid), integrated modeling, Experimental validation, plasma neutron source, Condensed Matter Physics, calibration, plasmas, collaboration, JET, neutron diagnostic, integrated modelling, energy

Abstract

An integrated modelling methodology for the calculation of realistic plasma neutron sources for the JET tokamak has been developed. The computational chain comprises TRANSP plasma transport and DRESS neutron spectrum calculations, and their coupling to the MCNP neutron transport code, bridging plasma physics and neutronics. In the paper we apply the developed methodology to the analysis of neutron emission properties of deuterium and helium plasmas at JET, and validate individual modelling steps against neutron diagnostic measurements. Two types of JET discharges are modelled-baseline-like and three-ion radio-frequency scenarios-due to their diversity in plasma heating, characteristics of the induced fast ion population, and the imprint of these on neutron emission properties. The neutron emission modelling results are quantitatively compared to the total neutron yield from fission chambers, neutron emissivity profiles from the neutron camera, neutron spectra from the time-of-flight spectrometer, and neutron activation measurements. The agreement between measured and calculated quantities is found to be satisfactory for all four diagnostic systems within the estimated experimental and computational uncertainties. Additionally, the effect of neutrons not originating from the dominating D(D, n)He-3 reactions is studied through modelling of triton burnup DT neutrons, and, in mixed D-He-3 plasmas, neutrons produced in the Be-9(D, n gamma)B-10 reaction on impurities. It is found that these reactions can contribute up to several percent to the total neutron yield and dominate the neutron activation of samples. The effect of MeV-range fast ions on the neutron activation of In-115 and Al-27 samples is measured and computationally validated.

Published

2021

32. Shutdown dose rate calculations with modified DEMO single sector model

Author

Christian Bachmann, Igor Lengar, Bor Kos, Luka Snoj, Aljaž Čufar, and Domen Kotnik

Subjects

Tokamak, Computer science, Mechanical Engineering, Nuclear engineering, Shutdown, Radiation, Blanket, law.invention, Nuclear Energy and Engineering, law, Sector model, General Materials Science, Boundary value problem, Skyshine, Dose rate, Civil and Structural Engineering

Abstract

A new approach for particle transport was used to calculate the Skyshine dose rates for the DEMO tokamak for the unsymmetrical case with one breeding blanket module removed for maintenance. Transport calculations for the large tokamaks, including DEMO and partly ITER, are usually performed in sector models postulating cyclic symmetry of geometry and source terms and applying reflecting boundary conditions on the sector edges. In the case of non-symmetric localized sources the sector models are not suitable. The calculation of shutdown dose rates, caused by one single tritium breeding blanket module moved from DEMO vacuum vessel into the upper maintenance hall, is an example of a localized radiation source and cannot be calculated in the standard way using a sector model. A new approach was followed for the calculations using the same sector model of DEMO, however with an according modification of the MCNP transport code. In this article the new approach is presented including its verification based on a simpler baseline model of DEMO. The results show that the obtained radiation dose distribution due to the one moved breeding blanket module differs by a factor of up to 2.8 from what would be obtained using a single sector model.

Published

2021

33. VALIDATION OF SERPENT FOR FUSION NEUTRONICS ANALYSIS AT JET

Author

Igor Lengar, Luka Snoj, Sean Conroy, Andrej Žohar, Žiga Štancar, Jet Contributors, and Paola Batistoni

Subjects

Physics, Neutron transport, Jet (fluid), serpent, mcnp, Nuclear engineering, Astrophysics::High Energy Astrophysical Phenomena, QC1-999, Serpent (symbolism), Fusion neutronics, neutron transport, Physics::Plasma Physics, jet

Abstract

Fusion neutronics analysis before and after experiments at JET is traditionally performed using Monte Carlo particle transport code Monte Carlo N-Particle. For redundancy and diversity reasons there is a need of an additional Monte Carlo code, such as Serpent 2, capable of fusion neutronics analysis. In order to validate the Serpent code for fusion applications a detailed model of JET was used. Neutron fluxes and reaction rates were calculated and compared for positions outside the tokamak vacuum vessel, in the vacuum vessel above the plasma and next to a limiter inside the vacuum vessel. For all detector positions with DD and DT neutron sources the difference between neutron fluxes calculated with both Monte Carlo codes were within 2σ statistical uncertainty and for most positions (more than 90 % of all studied positions) even within 1σ uncertainty. Fusion neutronics analysis in the JET tokamak with Serpent took on average 10 % longer but this can be improved by changing the threshold value for determination of the transport method used. With the work presented in this paper the Serpent Monte Carlo code was validated to be a viable alternative to MCNP for fusion neutronics analysis for the JET tokamak.

Published

2021

34. Silicon carbide diodes for neutron detection

Author

Adam Sarbutt, Vladimir Radulović, Robert Bernat, José Coutinho, Vitor J.B. Torres, Takeshi Ohshima, Takahiro Makino, Željko Pastuović, Yuichi Yamazaki, Klemen Ambrožič, Ivana Capan, Luka Snoj, Zoran Ereš, and Tomislav Brodar

Subjects

Nuclear and High Energy Physics, Physics - Instrumentation and Detectors, Schottky barrier, FOS: Physical sciences, 02 engineering and technology, Silicon carbide, 01 natural sciences, Radiation defects, chemistry.chemical_compound, 0103 physical sciences, Neutron detection, Neutron, Instrumentation, 010302 applied physics, Physics, Condensed Matter - Materials Science, Fissile material, Wide-bandgap semiconductor, Materials Science (cond-mat.mtrl-sci), Instrumentation and Detectors (physics.ins-det), 16. Peace & justice, 021001 nanoscience & nanotechnology, Engineering physics, Neutron temperature, Semiconductor detector, chemistry, 0210 nano-technology

Abstract

In the last two decades we have assisted to a rush towards finding a 3He-replacing technology capable of detecting neutrons emitted from fissile isotopes. The demand stems from applications like nuclear war-head screening or preventing illicit traffic of radiological materials. Semiconductor detectors stand among the strongest contenders, particularly those based on materials possessing a wide band gap like silicon carbide (SiC). We review the workings of SiC-based neutron detectors, along with several issues related to material properties, device fabrication and testing. The paper summarizes the experimental and theoretical work carried out within the E-SiCure project (Engineering Silicon Carbide for Border and Port Security), co-funded by the NATO Science for Peace and Security Programme. The main goal was the development of technologies to support the fabrication of radiation-hard silicon carbide detectors of special nuclear materials. Among the achievements, we have the development of successful Schottky barrier based detectors and the identification of the main carrier life-time-limiting defects in the SiC active areas, either already present in pristine devices or introduced upon exposure to radiation fields. The physical processes involved in neutron detection are described. Material properties as well as issues related to epitaxial growth and device fabrication are addressed. The presence of defects in as-grown material, as well as those introduced by ionizing radiation are reported. We finally describe several experiments carried out at the Jozef Stefan Institute TRIGA Mark II reactor (Ljubljana, Slovenia), where a set of SiC-based neutron detectors were tested, some of which being equipped with a thermal neutron converter layer. We show that despite the existence of large room for improvement, Schottky barrier diodes based on state-of-the-art 4 H -SiC are closing the gap between gas- and semiconductor-based detectors regarding their sensitivity.

Published

2021

35. APPLICATION OF THE JSIR2S CODE PACKAGE FOR SHUTDOWN DOSE RATE CALCULATIONS ON JET

Author

Rosaria Vilarri, Luka Snoj, Klemen Ambrožič, and Paola Batistoni

Subjects

Physics, Jet (fluid), Neutron transport, fusion, Tokamak, QC1-999, Octant (solid geometry), Radiation, Computational physics, law.invention, r2s, icrp74, shutdown dose rate, law, Ionization, jet, advantg, Variance reduction, gamma, Neutron activation

Abstract

In this paper we present a computational exercise for shut-down dose rate calculations for the JET tokamak using the in-house developed JSIR2S code package as part of its validation. The computation is performed in two parts: neutron transport and transport of secondary gamma radiation. In order to calculate neutron activation reaction rates with sufficiently low variance, hybrid variance reduction techniques using the ADVANTG code have been utilized. Probability based sampling of secondary source particles was performed. Calculated gamma dose rates after shut down are compared with dose rate measurements performed on site using ionization chambers. The C/E agreement for 1st octant is between 0.8 to 1 while statistically meaningfull results for the 2nd octant are yet to be obtained.

Published

2021

36. Nuclear Heating Measurements for Fusion and Fission Relevant Materials in the Jsi Triga Reactor

Author

Hubert Carcreff, Vladimir Radulović, Damien Fourmentel, Klemen Ambrožič, Christophe Destouches, Luka Snoj, and Nicolas Thiollay

Subjects

History, Nuclear Energy and Engineering, Polymers and Plastics, Mechanical Engineering, General Materials Science, Business and International Management, Industrial and Manufacturing Engineering, Civil and Structural Engineering

Published

2021

37. 3-D thermal and radiation-matter interaction simulations of a SiC solid-state detector for neutron flux measurements in JSI TRIGA Mark II research reactor

Author

Abdallah Lyoussi, Laurent Ottaviani, V. Valero, M. Carette, A. Volte, Luka Snoj, C. Reynard-Carette, H. Ghninou, Anže Pungerčič, and Vladimir Radulović

Subjects

Materials science, Thermonuclear fusion, 3-d simulations, Nuclear engineering, Physics, QC1-999, radiation-matter interaction, Radiation, neutron detection, TRIGA, thermal, chemistry.chemical_compound, chemistry, Neutron flux, silicon carbide, Silicon carbide, Neutron detection, Research reactor, Neutron, irradiation campaign

Abstract

Neutron detection is a relevant topic in the field of nuclear instrumentation. It is at the heart of the concerns for fusion applications (neutron diagnostics, measurements inside the Test Blanket Modules TBM) as well as for fission applications (in-core and ex-core monitoring, neutron mapping or safety applications in research reactors). Moreover, due to the even more harsh conditions of the future experimental reactors such as the Jules Horowitz Reactor (JHR) or International Thermonuclear Experimental Reactor (ITER), neutron detectors need to be adapted to high neutron and γ fluxes, high nuclear heating rates and high temperatures. Consequently, radiation and temperature hardened sensors with fast response, high energy resolution and stability in a mixed neutron and γ environment are required. All these requirements make wide-bandgap semiconductors and, more precisely, Silicon Carbide (SiC) serious candidates due to their intrinsic characteristics in such extreme environments. Thus, since the last decades, SiC-based detectors are developed and studied for neutron detection in various nuclear facilities. In this paper, a SiC-based neutron detector is 3-D designed and studied through thermal and radiation-matter interaction numerical simulations for a future irradiation campaign at the Jožef Stefan Institute TRIGA Mark II research reactor in Slovenia. Firstly, this paper presents the scientific background and issues of our SiC-based detectors. In a second part the 3-D geometry is shown. Thereafter, the 3-D numerical thermal simulation results are reported. Finally, the 3-D numerical radiation/matter interaction simulations results are presented.

Published

2021

38. The European Nuclear Experimental Educational Platform – ENEEP: Progress, Prospects and Remote Education Capabilities

Author

Vladimir Radulović, H. Böck, Attila Tormási, Štefan Čerba, Szabolcs Czifrus, Luka Snoj, Branislav Vrban, Anže Jazbec, Jakub Lüley, Ondřej Novák, Ľubomír Sklenka, Marcella Cagnazzo, Marcel Miglierini, Mario Villa, Filip Osusky, and Ján Haščík

Subjects

Czech, Engineering, nuclear science and technology, Coronavirus disease 2019 (COVID-19), business.industry, remote capabilities, Physics, QC1-999, experimental education activities, language.human_language, Engineering management, Young professional, Scientific development, Technical university, language, Relevance (information retrieval), Slovak, business, Curriculum

Abstract

The European Nuclear Experimental Educational Platform – ENEEP is currently being established by five European educational and research organizations in the framework of a Horizon 2020 project, initiated in 2019. The ENEEP partner institutions are the Jožef Stefan Institute (JSI, Slovenia), the Slovak University of Technology in Bratislava (STU, Slovak Republic), the Czech Technical University in Prague (CTU, Czech Republic), Technische Universität Wien (TU Wien, Austria) and the Budapest University of Technology and Economics (BME, Hungary). ENEEP is intended as an open educational platform, offering experimental hands-on education activities at the ENEEP partner facilities. ENEEP education activities will be offered in different formats (group and individual) and are targeted at university students at all educational levels and young professionals in the nuclear field. This paper gives an overview of the ENEEP project activities and the progress achieved thus far, highlighting the experimental capabilities which will be offered. In the first implementation phase, ENEEP will be based on a comprehensive set of experiments comprising the basics in Reactor Physics and Nuclear Engineering curricula, as well as more specific experiments focusing on particular aspects – investigated phenomena, types and working principles of detectors, etc. Subsequently, novel education activities will be introduced and implemented in ENEEP, following scientific development in nuclear science and technology and nuclear instrumentation detectors, stemming from research activities. Attention will be devoted to the development and optimization of remote education capabilities at the ENEEP partner institutions, of particular relevance during the current Covid-19 pandemic, which is responsible for major changes in education activities worldwide.

Published

2021

39. SILICON CARBIDE NEUTRON DETECTOR PROTOTYPE TESTING AT THE JSI TRIGA REACTOR FOR ENHANCED BORDER AND PORTS SECURITY

Author

Klemen Ambrožič, Takeshi Ohshima, Adam Sarbutt, Zoran Ereš, Ivana Capan, José Coutinho, Željko Pastuović, Robert Bernat, Luka Snoj, Yuichi Yamazaki, Takahiro Makino, and Vladimir Radulović

Subjects

010302 applied physics, Materials science, Physics::Instrumentation and Detectors, Nuclear engineering, Physics, QC1-999, 02 engineering and technology, 01 natural sciences, TRIGA, chemistry.chemical_compound, 020303 mechanical engineering & transports, 0203 mechanical engineering, chemistry, 0103 physical sciences, Silicon carbide, Neutron detection

Abstract

In 2016, the “E-SiCure” project (standing for “Engineering Silicon Carbide for Border and Port Security”), funded by the NATO Science for Peace and Security Programme was launched. The main objective is to combine theoretical, experimental and applied research towards the development of radiation-hard SiC-based detectors of special nuclear materials (SNM), with the end goal to enhance border and port security barriers. Prototype neutron detectors, configured as 4H-SiC-based Schottky barrier diodes, were developed for the detection of secondary charged particles (tritons, alphas and lithium atoms) which are the result of thermal neutron reactions on 10B and 6LiF layers above the surface of the 4H-SiC diodes. We designed a stand-alone prototype detection system, consisting of a preamplifier, shaping amplifier and a multichannel analyser operated by a laptop computer, for testing of neutron detector prototypes at the Jožef Stefan Institute (JSI) TRIGA reactor using a broad beam of reactor neutrons. The reverse bias for the detector diode and the power to electronic system were provided by a standalone battery-powered voltage source. The detector functionality was established through measurements using an 241Am alpha particle source. Two dedicated experimental campaigns were performed at the JSI TRIGA reactor. The registered pulse height spectra from the detectors, using both 10B and 6LiF neutron converting layers, clearly demonstrated the neutron detection abilities of the SiC detector prototypes. The computed neutron detection sensitivity of the single prototype detectors demonstrates that scaling SiC detectors into larger arrays, of dimensions relevant for border and port radiation detectors, could enable neutron sensitivity levels matching gas-based detector technology.

Published

2021

40. On teaching experimental reactor physics in times of pandemic

Author

Jan Malec, Anže Jazbec, Igor Lengar, Luka Snoj, Ali Al-Adili, Sebastjan Rupnik, Michael Österlund, Andreas Solders, and Vladimir Radulović

Subjects

education, training, Physics, QC1-999, quarantine, reactor physics, Didactics, Acceleratorfysik och instrumentering, Didaktik, Accelerator Physics and Instrumentation, Aeronautics, Pandemic, ComputingMilieux_COMPUTERSANDEDUCATION, nuclear reactor

Abstract

The COVID-19 induced restrictions have prevented reactor physics students from attending in-person reactor physics exercises which are a vital part of their education. Jožef Stefan Institute has organized remote exercises with the help of off-the-shelf technology, including multiple videoconferencing setups, remote desktop software, portable cameras, a dome camera, shared spreadsheets, and a common whiteboard. The students were encouraged to actively participate in the exercises by giving instructions to the reactor operator, asking and answering questions, logging data, operating digital acquisition systems, and performing analysis during the exercise. The first remote exercises were organized as a five-day course of experimental reactor physics for students from Uppsala University. The feedback was collected after the course using an anonymous online form and was generally positive but has revealed some problems with sound quality which were resolved later. The Jožef Stefan Institute can also organize a remote course during a full lockdown when the reactor is not able to operate using the in-house developed Research Reactor Simulator based on a point kinetics approximation and a simple thermohydraulic module.

Published

2021

41. Simultaneous, robot-compatible γ-ray spectroscopy and imaging of an operating nuclear reactor

Author

Malcolm J. Joyce, Luka Snoj, Anze Jazbec, Ioannis Tsitsimpelis, Andrew West, Philip A. Martin, Mauro Licata, Michael Aspinall, and Barry Lennox

Subjects

Materials science, business.industry, 010401 analytical chemistry, Detector, estimation and classification based on sensor data, detection, Collimator, Robotics and automation, Scintillator, Nuclear reactor, Gimbal, 01 natural sciences, Particle detector, 0104 chemical sciences, TRIGA, law.invention, Optics, Data acquisition, law, Electrical and Electronic Engineering, business, Instrumentation, environmental monitoring and control

Abstract

The design and test of a robot-compatible, radiation detection instrument providing simultaneous $\gamma $ -ray imaging and $\gamma $ -ray spectroscopy is described. The sensing system comprises a cerium bromide inorganic scintillation detector and a cylindrical, lead slot collimator that is configured with a robot-compatible, on-board data acquisition system. The mount for the sensor is a lightweight, bespoke 3-axis gimbal actuated by servos for pan, tilt and rotation of the collimator for imaging capability. This paper discusses the integration of this relatively low-cost radiation detection apparatus with a commercially available, Robot-Operating-System-controlled robotic platform (a Clearpath Robotics™ Jackal). The detection system is compliant with the power and mass payload constraints of the robot. Its performance has been evaluated by means of two practical examples: a) measurements in a laboratory environment to assess the ability of the system to resolve two caesium-137 point sources, and b) deployment at the Jožef Stefan Institute TRIGA Mark II research reactor to assess the ability of the system to characterise the $\gamma $ -ray emission at 1 kW from a horizontal tangential beam port in the reactor hall and from the reactor sample pool above the core.

Published

2020

42. Dose rate calculations at beam tube no. 5 of the JSI TRIGA mark II research reactor using Monte Carlo method

Author

Luka Snoj, B. Kos, Anže Jazbec, and Klemen Ambrožič

Subjects

Radiation, Materials science, Nuclear engineering, Monte Carlo method, 010403 inorganic & nuclear chemistry, 01 natural sciences, 030218 nuclear medicine & medical imaging, 0104 chemical sciences, TRIGA, 03 medical and health sciences, 0302 clinical medicine, Electromagnetic shielding, Neutron, Variance reduction, Research reactor, Irradiation, Beam (structure)

Abstract

Monte Carlo N-Particle (MCNP) transport code accelerated by AutomateD VAriaNce reducTion Generator (ADVANTG) code was used to simulate neutron and prompt gamma particles emitted from TRIGA research reactor during operation. Firstly, the method was validated by measuring dose rates around open beam port number 5 was unplugged. Neutron and gamma dose rates inside the reactor hall in the vicinity of the beam port were calculated and compared to the measurements. Due to the satisfactory agreement, the method was later used to design external shielding for the same beam port when it was upgraded - special mechanism was installed that allows irradiation of larger samples. Computational analysis of the proposed shielding configuration provided acceptable dose rate levels inside the reactor hall. When the shield was constructed, calculated dose rates were confirmed by the actual measurements. No modifications were needed.

Published

2020

43. Assessing naturalness of European floodplain hydromorphology using remote sensing products and other consistent large scale data

Author

Trine Christiansen, Lidija Globevnik, Anne Lyche Solheim, Muhammet Azlak, Sebastian Birk, Luka Snoj, Jochem Kail, and Kathrin Januschke

Subjects

geography, geography.geographical_feature_category, Naturalness, Floodplain, Remote sensing (archaeology), Environmental science, Large scale data, Remote sensing

Abstract

The spatial reference framework is the lateral extent of the river channel and its floodplain, named “flood-prone area extent”. Due to human interventions into the hydrological cycle and morphological alterations of the river channel and its floodplain, some areas that were regularly flooded once, may not experience such flooding today. We characterize them as “former floodplains”. Floodplains flooded now are named “active floodplains”. The analysis is done on the spatial resolution level named “Functional Elementary Catchment” (FEC) of the European catchments and Rivers network system (Ecrins) database and for the flood-prone areas in Europe that include former and active floodplains with river channels. It is named “Potential flood prone area”. In the first step we defined floodplains typology. For the assessment part we developed indicators of floodplain forms and processes, defined their benchmark condition and performed quality classification. Here, we describe what spatial data we used and what data we still miss to produce reliable assessment. The spatial layer “Potential flood-prone area extent” was derived from two spatial layers, Potential Riparian Zone Delineation of the Copernicus Land Monitoring Service and JRC flood hazard map for Europe 100-year return period, a result of flood model “LisFlood”. The candidate list of typology factors included 31 factors derived from various databases such are Ecrins, MARS, FAO, Copernicus, WorldClim, PCGLOBEWB and IHME. Factors represent abiotic state before human intervention into rivers and floodplains and are grouped into regions, climate, morphology, hydrology, geology and physics – river dynamics. The calculated factors are reasonably covering the assessment area (95% - 99%) with the exception of the physics – river dynamics factors. This information was obtained for less than 30% of European area. The selection of factors defining floodplain types was based on the criterion of adequate spatial coverage, reliability and non-redundancy. As a result, floodplain types were derived from seven factors, three morphological (river average altitude and slope and average floodplain width), one geological (dominant catchment geo-chemistry) and three hydrological factors (specific runoff as mean annual discharge divided by catchment area, high flow duration and high flow pulses). Hydrological and morphological factors are only approximations to the natural state, so we propose to further develop databases providing information on river and floodplain hydromorphology prior to major human interventions.Indicators of floodplain forms are derived from two layers, Riparian Zone Land Cover/Land Use and High Resolution Water & Wetness of the Copernicus Land Monitoring Service. The land use layer provides a good basis for assessing the current distribution of floodplain habitats. We also estimate the size of the active natural floodplains using wetness data, but the results can be improved with systematic European wide information on present hydrotechnical structures and hydromorphological alterations. Such data would also support assessment of floodplain ecological condition and management options.

Published

2020

44. Silicon carbide neutron detector testing at the JSI TRIGA reactor for enhanced border and port security

Author

Zoran Ereš, José Coutinho, Vladimir Radulović, Takeshi Ohshima, Yuichi Yamazaki, Klemen Ambrožič, Luka Snoj, Ivana Capan, Željko Pastuović, Robert Bernat, and Adam Sarbutt

Subjects

Nuclear reaction, Nuclear and High Energy Physics, Context (language use), Silicon carbide, Neutron converter, 7. Clean energy, 01 natural sciences, TRIGA, chemistry.chemical_compound, Neutron flux, 0103 physical sciences, Neutron detection, Neutron, Instrumentation, Diode, 010302 applied physics, Physics, 010308 nuclear & particles physics, business.industry, 16. Peace & justice, Interdisciplinary Natural Sciences, chemistry, silicon carbide, neutron detection, neutron converter, JSI TRIGA reactor, Optoelectronics, business

Abstract

In 2016, the NATO Science for Peace and Security Programme funded research project ”Engineering Silicon Carbide for Border and Port Security” — E-SiCure was launched, its objective being the development of radiation-hard silicon carbide (SiC) based detectors of special nuclear materials (SNM), with the aim to enhance border and port security barriers. Detector prototypes based on SiC Schottky Barrier Diodes (SBDs) and neutron converter films were developed. This paper presents the results of a dedicated experimental testing campaign performed at the Jožef Stefan Institute (JSI) TRIGA reactor in which several SiC detector prototypes equipped with 10 B and 6 LiF converter films were irradiated in the Dry Chamber of the reactor. The obtained results demonstrate a clearly measurable neutron response, which varies linearly with the neutron flux. The measured particle spectra from the SiC detectors exhibit a clear structure, attributable to the nature and energy of secondary particles originating as reaction products from nuclear reactions involving 10 B and 6 Li isotopes. The determined sensitivity of the detectors, their active volume being 1 mm × 1 mm × 25 μ m , 1 mm × 1 mm × 69 μ m and 1 mm × 1 mm × 170 μ m , was of the order of 2 × 10−5 counts per second, per unit of neutron flux [counts s−1 per n cm−2s−1] (for neutron energies between 0 and 5 eV). Scaling the detection sensitivity by a factor of 1 0 5 , i.e. to an array with a surface of around 20 cm × 2 m, comparable to large B F 3 or 3 He detectors, would theoretically enable an overall sensitivity of around 2 counts s−1 per n cm−2s−1, which is already comparable to typical neutron sensitivity values of gas detectors, in the range from several to over 100 counts s−1 per n cm−2s−1. Due to its outstanding tolerance to harsh environments (including high temperatures and radiation fields) and superior electronic properties when compared to other semiconductors, SiC is a promising base material for the fabrication of solid-state detectors with stable and long life-time. Improvements in sensitivity combined with the capability of fabricating large modules (SiC arrays), could make SiC an important detection technology, applicable also in the context of border and port security barrier monitoring.

Published

2020

45. Usage of multiple fission cells for neutron flux measurements during rod-insertion method

Author

Andrej Žohar, Sebastjan Rupnik, Igor Lengar, Vid Merljak, Marjan Kromar, and Luka Snoj

Subjects

Materials science, control rod worth measurements, 010308 nuclear & particles physics, Fission, fission cells, Nuclear engineering, Control rod, Physics, QC1-999, Flux, 01 natural sciences, Signal, TRIGA, research reactor, Neutron flux, Ionization, 0103 physical sciences, combining signals, Research reactor

Abstract

The measurements of physical parameters of the TRIGA reactor and Nuclear power plant Krško (NEK) reactor cores have been in the past performed on hand of the neutron flux signal obtained from uncompensated ionization cells and by employment of the a digital meter of reactivity (DMR). At the TRIGA reactor only one ionization cell is currently used for flux measurements. During the insertion of one control rod the neutron flux distribution is significantly altered affecting the flux measurements of inserting different control rods. The problem is presently solved by assigning a correction factor to each control rod what introduces an additional uncertainty. In the present paper the implementation of four fission cells for reactivity measurements is presented. In this way determining the correct gamma background and its subtraction, performed by DMR algorithms, becomes less important as previously by using ionization chambers. The larger number of detectors also reduces the flux redistribution effects on the signal during individual control rod movements.

Published

2020

46. Producing Useful Chemicals Using a Nuclear Reactor

Author

Vesna Najdanovic-Visak, Malcolm J. Joyce, Arran George Plant, Anže Jazbec, and Luka Snoj

Subjects

organic chemicals, 010405 organic chemistry, 020209 energy, Physics, QC1-999, Radiochemistry, Ethyl acetate, technology, industry, and agriculture, radiolysis, 02 engineering and technology, neutron radiation effects, 01 natural sciences, 0104 chemical sciences, chemistry.chemical_compound, chemistry, Yield (chemistry), chemical analysis, Radiolysis, Solketal, 0202 electrical engineering, electronic engineering, information engineering, Glycerol, chemical engineering, Irradiation, Gas chromatography, Ethylene glycol

Abstract

In this paper, the irradiation of glycerol and ethylene glycol by either mixed (neutron-γ) or γ-only (γ) fields at the TRIGA reactor of the Jožef Stefan Institute is described. This is highly relevant to future applications of fission reactor systems to produce useful feedstock derivatives from organic waste, beyond the production of heat and power. Samples of glycerol and ethyl glycol have been exposed to neutron-gamma radiation with fast neutron fluxes ranging from 7.7×1010 to 3×1012 cm−2s−1 and gamma-only irradiation at maximum dose-rates of 492 and 10 kGy hr−1, respectively. A study of the dependence of product yield versus absorbed dose has been conducted, for total dose ranges of 1 to 100 kGy. The products of these exposures have been identified through Gas Chromatography – Mass Spectrometry (GC-MS) techniques. Analysis comparing neutron-gamma irradiated samples of ethylene glycol and glycerol with gamma-irradiated samples shows no detectable qualitative difference between either irradiation type. Although, additional radiolysis products were detected when compared with available literature; ethyl acetate from ethylene glycol and solketal from glycerol. Quantitatively, neutron-gamma irradiation seems to be less effective at producing acetaldehyde from ethylene glycol, compared with gamma-only which can be explained through neutron moderation and consequent heating effects due to the borosilicate vials.

Published

2020

47. Engineering Silicon Carbide for Enhanced Borders and Ports Security

Author

Vladimir Radulović, Luka Snoj, Robert Bernat, Vitor J.B. Torres, Adam Sarbutt, Zoran Ereš, Tomislav Brodar, Takahiro Makino, Klemen Ambrožič, Ivana Capan, Takeshi Ohshima, Željko Pastuović, Yuichi Yamazaki, and José Coutinho

Subjects

chemistry.chemical_compound, Materials science, chemistry, Detector, Silicon carbide, Neutron, Nuclear material, Radiation, Engineering physics, Particle detector

Abstract

Developing new state-of-the-art, low-cost and radiation hard detectors is an extremely difficult challenge which can be tackled only by a multisciplinary group of scientists and engineers from various fields having access to different infrastructure.

Published

2020

48. Depth Profile Analysis of Deep Level Defects in 4H- SiC Introduced by Radiation

Author

Takeshi Ohshima, Tomislav Brodar, Luka Snoj, Željko Pastuović, Ivana Capan, Vladimir Radulović, and Luka Bakrač

Subjects

Materials science, Silicon, General Chemical Engineering, chemistry.chemical_element, 02 engineering and technology, 01 natural sciences, Molecular physics, Ion, Inorganic Chemistry, silicon carbide, Vacancy defect, 0103 physical sciences, lcsh:QD901-999, Electron beam processing, ion implantation, General Materials Science, Neutron, Irradiation, defects, 010302 applied physics, DLTS, Physics, neutron radiation, Neutron radiation, 021001 nanoscience & nanotechnology, Condensed Matter Physics, Ion implantation, chemistry, lcsh:Crystallography, 0210 nano-technology

Abstract

Deep level defects created by implantation of light-helium and medium heavy carbon ions in the single ion regime and neutron irradiation in n-type 4H-SiC are characterized by the DLTS technique. Two deep levels with energies 0.4 eV (EH1) and 0.7 eV (EH3) below the conduction band minimum are created in either ion implanted and neutron irradiated material beside carbon vacancies (Z1/2). In our study, we analyze components of EH1 and EH3 deep levels based on their concentration depth profiles, in addition to (&minus, 3/=) and (=/&minus, ) transition levels of silicon vacancy. A higher EH3 deep level concentration compared to the EH1 deep level concentration and a slight shift of the EH3 concentration depth profile to larger depths indicate that an additional deep level contributes to the DLTS signal of the EH3 deep level, most probably the defect complex involving interstitials. We report on the introduction of metastable M-center by light/medium heavy ion implantation and neutron irradiation, previously reported in cases of proton and electron irradiation. Contribution of M-center to the EH1 concentration profile is presented.

Published

2020

49. Utilisation of JSI TRIGA Pulse Experiments for Testing of Nuclear Instrumentation and Validation of Transient Models

Author

I. Vavtar, Anže Pungerčič, and Luka Snoj

Subjects

fuchs-hansen model, Maximum power principle, 010308 nuclear & particles physics, maximum power, 020209 energy, Instrumentation, Nuclear engineering, Physics, QC1-999, total energy released, 02 engineering and technology, 01 natural sciences, full width at half maximum, TRIGA, Power (physics), Pulse (physics), Full width at half maximum, pulse experiments, 0103 physical sciences, 0202 electrical engineering, electronic engineering, information engineering, Environmental science, Transient (oscillation), nordheim-fuchs model, Energy (signal processing)

Abstract

A pulse experiment model was validated in order to support future pulse experimental campaigns. All pulse experiments data was collected and are publicly available at http://trigapulse.ijs.si/. A comparison of the measured pulse physical parameters (maximal power, total released energy and full width at half maximum) and theoretical predictions (Fuchs-Hansen and the Nordheim-Fuchs models) was made.

Published

2020

50. Radiation hardness studies and detector characterisation at the JSI TRIGA reactor

Author

Hubert Carcreff, Luka Snoj, Vladimir Cindro, Marko Mikuž, Anže Pungerčič, Igor Lengar, Aljaž Čufar, Loïc Barbot, J. F. Villard, Gregor Kramberger, Damien Fourmentel, Tanja Goričanec, A. Gruel, Anže Jazbec, Žiga Štancar, Christophe Destouches, Vladimir Radulović, Klemen Ambrožič, Sebastjan Rupnik, Igor Mandić, Gašper Žerovnik, and Andrej Žohar

Subjects

Materials science, Large Hadron Collider, Physics::Instrumentation and Detectors, Nuclear engineering, Physics, QC1-999, Monte Carlo method, Detector, Radiation, neutron radiation effects, radiation hardness, testing, TRIGA, nuclear measurements, reactor instrumentation, Neutron, Irradiation, triga, gamma-ray effects, Radiation hardening, detectors

Abstract

The JSI TRIGA reactor features several in-core and ex-core irradiation facilities, each having different properties, such as neutron/gamma flux intensity, spectra and irradiation volume. A series of experiments and calculations was performed in order to characterise radiation fields in irradiation channel thus allowing users to perform irradiations in a well characterised environment. Since 2001 the reactor has been heavily used for radiation hardness studies for components used at accelerators such as the Large Hadron Collider (LHC) at CERN. Since 2010 it has been extensively used for testing of new detectors and innovative data acquisition systems and methods developed and used by the CEA. Recently, several campaigns were initiated to characterise the gamma field in the reactor and use the experimental data for improvement of the treatment of delayed gammas in Monte Carlo particle transport codes. In the future it is planned to extend the testing options by employing pulse mode operation, installation of a high energy gamma ray irradiation facility and allow irradiation of larger samples at elevated temperature.

Published

2020