Your search keyword '"Talou P."' showing total 511 results

1. Time Evolution of Prompt Gamma-Ray Emission in $^{252}$Cf(sf) and $^{233,235}$U($n$,f) Reactions

Author

Talou, Patrick, Lovell, Amy E., Stetcu, Ionel, Rusev, Gencho, Kawano, Toshihiko, and Jandel, Marian

Subjects

Nuclear Theory

Abstract

We investigate the time evolution of prompt fission $\gamma$ emission due to the presence of ns to ms isomers in the fragments produced in the neutron-induced fission of $^{233,235}$U and in the spontaneous fission of $^{252}$Cf. Calculations performed with the CGMF fission event generator are compared with recent experimental data on $^{252}$Cf(sf) and $^{235}$U($n$,f) obtained with the DANCE+NEUANCE setup at the Los Alamos Neutron Science Center. Of particular interest are the average $\gamma$-ray energy spectrum as a function of time since scission, $\phi(\epsilon_\gamma,t)$, the increase of the average $\gamma$-ray multiplicity over time, $N_\gamma(t)$, and its evolution in time as a function of the fission fragment mass, $N_\gamma(A,t)$. The time evolution of isomeric ratios in post-neutron emission fission fragments can be defined and used to test and reveal some deficiencies in our knowledge of the low-lying levels of neutron-rich nuclei produced in fission reactions.

Published

2025

2. Calculated covariance matrices for fission product yields using BeoH

Author

Lovell A. E., Kawano T., and Talou P.

Subjects

Physics, QC1-999

Abstract

Fission product yields (FPY) are important for a variety of applications (reactor neutronics, spent fuel, dosimetry, radiochemistry, etc.) and are currently included in many of the evaluated libraries around the world. The FPYs in the current US evaluation, ENDF/B-VIII.0, are mainly based on the 1994 evaluation of England and Rider and have only had slight updates—such as the inclusion of a 2 MeV point for 239Pu—since their development. Additionally, only mean values and uncertainties are included in the evaluation, not full correlations. Los Alamos National Laboratory, in collaboration with several other institutes, has been working on an updated evaluation for the FPYs of 239Pu(n,f), 235U(n,f), 238U(n,f), and 252Cf(sf) using the deterministic, Hauser-Feshbach, fission fragment decay code, BeoH. BeoH calculates the FPYs consistently with many other prompt and delayed fission observables, explicitly taking into account multi-chance fission and ensuring consistency between observables. In addition to providing updated means and uncertainties for the FPYs on a pointwise energy grid from thermal to 20 MeV, we calculate correlations between all FPYs at each incident energy and across incident energies. Here, we discuss the development of these covariance matrices, differences in the correlations between FPYs based on the parameters that are included in the model optimization, and correlations across incident energies for neutron-induced fission.

Published

2023

3. Nuclear data activities for medium mass and heavy nuclei at Los Alamos

Author

Mumpower M. R., Sprouse T. M., Kawano T., Herman M. W., Lovell A. E., Misch G. W., Neudecker D., Sasaki H., Stetcu I., and Talou P.

Subjects

Physics, QC1-999

Abstract

Nuclear data is critical for many modern applications from stockpile stewardship to cutting edge scientific research. Central to these pursuits is a robust pipeline for nuclear modeling as well as data assimilation and dissemination. We summarize a small portion of the ongoing nuclear data efforts at Los Alamos for medium mass to heavy nuclei. We begin with an overview of the NEXUS framework and show how one of its modules can be used for model parameter optimization using Bayesian techniques. The mathematical framework affords the combination of different measured data in determining model parameters and their associated correlations. It also has the advantage of being able to quantify outliers in data. We exemplify the power of this procedure by highlighting the recently evaluated 239Pu cross section. We further showcase the success of our tools and pipeline by covering the insight gained from incorporating the latest nuclear modeling and data in astrophysical simulations as part of the Fission In R-process Elements (FIRE) collaboration. We advocate for the adoption of tranmission protocols such as the Unified Reaction Structures for Astrophysics (URSA) for the rapid inclusion of nuclear data into astrophysical simulations.

Published

2023

4. The Extension of the Hauser-Feshbach Fission Fragment Decay Model to Multi-chance Fission and its Application to 239Pu

Author

Lovell A. E., Kawano T., Okumura S., Mumpower M. R., Stetcu I., and Talou P.

Subjects

Physics, QC1-999

Abstract

The Hauser-Feshbach fission fragment decay model, HF3D, calculates the statistical decay of fission fragments through both prompt and delayed neutron and γ-ray emissions in a deterministic manner. While previously limited to the calculation of only first-chance fission, the model has recently been extended to include multi-chance fission, up to neutron incident energies of 20 MeV. The deterministic decay takes as input prescission quantities–fission probabilities, pre-fission neutron energies, and the average energy causing fission– and post-scission quantities–yields in mass, charge, total kinetic energy, spin, and parity. From those fission fragment initial conditions, the full decay is followed through both prompt and delayed particle emissions. The evaporation of the prompt neutrons and γ rays is calculated through the Hauser-Feshbach statistical theory, taking into account the competition between neutron and γ-ray emission, conserving energy, spin, and parity. The delayed emission is taken into account using time-independent calculation using decay data. This whole formulation allows for the calculation of prompt neutron and γ-ray properties, such as multiplicities and energy distributions, both independent and cumulative fission yields, and delayed neutron observables, in a consistent framework. Here, we describe the implementation of multi-chance fission into the HF3D model, and show an example of prompt and delayed quantities beyond first-chance fission, using the example of neutron-induced fission on 239Pu. This expansion represents significant progress in consistently modeling the emission of prompt and delayed particles from fissile systems.

Published

2023

5. Semi-automated pipeline for generating personalised cerebrovascular models

Author

Sharifzadeh-Kermani, Alireza, Shen, Jiantao, Argus, Finbar, Dempsey, Sergio, Wright, Jethro, Kwon, Eryn, Holdsworth, Samantha, Maso Talou, Gonzalo, and Safaei, Soroush

Published

2024

6. Visualizing the human olfactory projection and ancillary structures in a 3D reconstruction

Author

Low, Victoria F., Lin, Chinchien, Su, Shan, Osanlouy, Mahyar, Khan, Mona, Safaei, Soroush, Maso Talou, Gonzalo, Curtis, Maurice A., and Mombaerts, Peter

Published

2024

7. Measuring global cerebrovascular pulsatility transmission using 4D flow MRI

Author

Dempsey, Sergio, Safaei, Soroush, Holdsworth, Samantha J., and Maso Talou, Gonzalo D.

Published

2024

8. An interaction graph approach to gain new insights into mechanisms that modulate cerebrovascular tone

Author

Dempsey, Sergio, Argus, Finbar, Maso Talou, Gonzalo Daniel, and Safaei, Soroush

Published

2024

9. Anisotropy in fission fragment and prompt neutron angular distributions

Author

Lovell A.E., Talou P., Stetcu I., and Kelly K.J.

Subjects

Physics, QC1-999

Abstract

Several physics mechanisms can lead to the deviation from an isotropic angular distribution for both fission fragments and the neutrons that are emitted during the fission event. Two of these effects have recently been implemented into CGMF, the Monte Carlo fission event generator developed at Los Alamos National Laboratory: angular distribution sampling for fission fragments and pre-equilibrium neutrons (those emitted before the compound nucleus forms). Using these new developments, we show that the anisotropy of the neutrons reflects the anisotropy of the fission fragments, in particular as the outgoing energy of neutrons increases. Correlations between the fission fragment and neutron anisotropies could be used to extract the fission fragment anisotropy from the neutron angular distributions.

Published

2021

10. Diffeomorphic Multi-Resolution Deep Learning Registration for Applications in Breast MRI

Author

French, Matthew G., Talou, Gonzalo D. Maso, Gamage, Thiranja P. Babarenda, Nash, Martyn P., Nielsen, Poul M., Doyle, Anthony J., Iglesias, Juan Eugenio, Balbastre, Yaël, and Young, Sean I.

Subjects

Electrical Engineering and Systems Science - Image and Video Processing, Computer Science - Computer Vision and Pattern Recognition, Computer Science - Machine Learning

Abstract

In breast surgical planning, accurate registration of MR images across patient positions has the potential to improve the localisation of tumours during breast cancer treatment. While learning-based registration methods have recently become the state-of-the-art approach for most medical image registration tasks, these methods have yet to make inroads into breast image registration due to certain difficulties-the lack of rich texture information in breast MR images and the need for the deformations to be diffeomophic. In this work, we propose learning strategies for breast MR image registration that are amenable to diffeomorphic constraints, together with early experimental results from in-silico and in-vivo experiments. One key contribution of this work is a registration network which produces superior registration outcomes for breast images in addition to providing diffeomorphic guarantees.

Published

2023

11. Solving one-dimensional penetration problem for fission channel in the statistical Hauser-Feshbach theory

Author

Kawano, Toshihiko, Talou, Patrick, and Hilaire, Stephane

Subjects

Nuclear Theory

Abstract

We solve the Schr\"{o}dinger equation for an arbitrary one-dimensional potential energy to calculate the transmission coefficient in the fission channel of compound nucleus reactions. We incorporate the calculated transmission coefficients into the statistical Hauser-Feshbach model calculation for neutron-induced reactions on $^{235,238}$U and $^{239}$Pu. The one-dimensional model reproduces the evaluated fission cross section data reasonably well considering the limited number of model parameters involved. A resonance-like structure appears in the transmission coefficient for a double-humped fission barrier shape that includes an intermediate well, which is understood to be a quantum mechanical effect in the fission channel. The calculated fission cross sections for the neutron-induced reactions on $^{235,238}$U and $^{239}$Pu all exhibit a similar structure.

Published

2023

12. Synthesizing Affective Neurophysiological Signals Using Generative Models: A Review Paper

Author

Nia, Alireza F., Tang, Vanessa, Talou, Gonzalo Maso, and Billinghurst, Mark

Subjects

Computer Science - Human-Computer Interaction, Computer Science - Artificial Intelligence, Computer Science - Machine Learning, Quantitative Biology - Neurons and Cognition

Abstract

The integration of emotional intelligence in machines is an important step in advancing human-computer interaction. This demands the development of reliable end-to-end emotion recognition systems. However, the scarcity of public affective datasets presents a challenge. In this literature review, we emphasize the use of generative models to address this issue in neurophysiological signals, particularly Electroencephalogram (EEG) and Functional Near-Infrared Spectroscopy (fNIRS). We provide a comprehensive analysis of different generative models used in the field, examining their input formulation, deployment strategies, and methodologies for evaluating the quality of synthesized data. This review serves as a comprehensive overview, offering insights into the advantages, challenges, and promising future directions in the application of generative models in emotion recognition systems. Through this review, we aim to facilitate the progression of neurophysiological data augmentation, thereby supporting the development of more efficient and reliable emotion recognition systems.

Published

2023

13. Late Prompt Fission Gamma Rays from 235U(n,f) and 252Cf(sf)

Author

Rusev G., Bond E. M., Bredeweg T. A., Couture A., O’Donnell J. M., Jandel M., Lovell A.E., Mosby S., Prokop C. J., Stetcu I., Talou P., and Ullmann J. L.

Subjects

Physics, QC1-999

Abstract

Two measurements of fission γ rays were performed with the DANCE and NEUANCE arrays using the reactions 235 U(n, f) and 252 Cf(sf). Utilizing the fast time response of the detectors and a method for estimating the accidental background, we obtained the energy spectrum of the late prompt fission γ rays as a function of the time since fission. The experimental results are compared with predictions of the code CGMF folded with GEANT4 simulations of the detector response.

Published

2020

14. Parameter Optimization and Sensitivity Studies of Spontaneous Fission with FREYA

Author

Vogt R., Randrup J., Talou P., Van Dyke J. T., and Bernstein L. A.

Subjects

Physics, QC1-999

Abstract

For many years, the state of the art for simulating fission in transport codes amounted to sampling from average distributions. However, such "average" fission models have limited capabilities. Energy is not explicitly conserved and no correlations are available because all particles are emitted independently. However, in a true fission event, the emitted particles are correlated. Recently, Monte Carlo codes generating complete fission events have been developed, thus allowing the use of event-by-event analysis techniques. Such techniques are particularly useful because the complete kinematic information is available for the fission products and the emitted neutrons and photons. It is therefore possible to extract any desired observables, including correlations. The fast event-by-event fission code FREYA (Fission Reaction Event Yield Algorithm) generates large samples of complete fission events, employing only a few physics-based parameters. A recent optimization of these parameters for the isotopes in FREYA that undergo spontaneous fission is described and results are presented. The sensitivity of neutron observables in FREYA to the input yield functions is also discussed and the correlation between the average neutron multiplicity and fragment total kinetic energy is quantified.

Published

2020

15. The Los Alamos fission yield evaluation pipeline

Author

Mumpower M. R., Verriere M., Lovell A. E., Kawano T., Stetcu I., and Talou P.

Subjects

Physics, QC1-999

Abstract

The nuclear data team at Los Alamos National Laboratory has undertaken a campaign to construct new fission yield evaluation. Significant advances have been made on a number of fronts. Nuclear potential energy surfaces can now be generated with the newly developed MicMac code based off the Finite Range Liquid-Drop Model (FRLDM). This model can be incorporated into the Los Alamos de-excitation framework codes BeOH and CGMF to perform modeling of prompt, independent (IFY) and cumulative (CFY) fission yields that take into account prompt and beta-delayed neutrons and photons consistent with decay data. This is in stark contrast to what exists in evaluated nuclear data libraries today, where only a few incident energy points are used with limited physical insights and no consistency between IFY, CFY and decay data. We highlight the latest progress with application of neutron-induced fission of 235 U and 239 Pu.

Published

2020

16. Quantified uncertainties in fission yields from machine learning

Author

Lovell A.E., Mohan A.T., Talou P., and Chertkov M.

Subjects

Physics, QC1-999

Abstract

As machine learning methods gain traction in the nuclear physics community, especially those methods that aim to propagate uncertainties to unmeasured quantities, it is important to understand how the uncertainty in the training data coming either from theory or experiment propagates to the uncertainty in the predicted values. Gaussian Processes and Bayesian Neural Networks are being more and more widely used, in particular to extrapolate beyond measured data. However, studies are typically not performed on the impact of the experimental errors on these extrapolated values. In this work, we focus on understanding how uncertainties propagate from input to prediction when using machine learning methods. We use a Mixture Density Network (MDN) to incorporate experimental error into the training of the network and construct uncertainties for the associated predicted quantities. Systematically, we study the effect of the size of the experimental error, both on the reproduced training data and extrapolated predictions for fission yields of actinides.

Published

2020

17. New paradigm for nuclear data evaluation

Author

Herman M., Brown D.A., Chadwick M.B., Haeck W., Kawano T., Neudecker D., Talou P., Trkov A., and White M.C.

Subjects

Physics, QC1-999

Abstract

A new paradigm for nuclear reaction data evaluations is proposed to produce adjusted libraries that take into account integral experiments on the same footing as the differential ones. These evaluations will provide comprehensive covariance matrices including cross-correlations among different materials/reactions that are critical for realistic propagation of data uncertainties to integral quantities. The new approach should also reduce error compensation issues and facilitate updating of the library to account for new or corrected experiments and advances in reaction modeling.

Published

2020

18. Using CGMF to estimate corrections for fission yields measured via γ-ray spectroscopy

Author

Jaffke P., Talou P., Devlin M., and Fotiades N.

Subjects

Physics, QC1-999

Abstract

Fission product yields have been inferred using γ-ray spectroscopy for several decades. Typically, these efforts have focused on even-Z even-A fission products as their nuclear structure are less complicated. To further simplify the situation, it is often assumed that no side-feeding to the ground-state occurs and multiplicity cuts have a negligible effect on the inferred yields. Using CGMF, a Hauser-Feshbach statistical decay model for the primary fission fragments, we estimate the impact of these assumptions and determine corrections for specific fission product yields. We report on these corrections and investigate their sensitivity to various nuclear parameters, specifically the spin distribution of the fission fragments and the assumed nuclear structure. Our results indicate that even in the simplest of cases, say the 2+ → 0+ transitions in even-Z even-A fragments, average level corrections are on the order of 75%.

Published

2020

19. The Los Alamos evaluation of $^{239}$Pu neutron-induced reactions in the fast energy range

Author

Mumpower, M. R., Neudecker, D., Kawano, T., Herman, M., Kleedtke, N., Lovell, A. E., Stetcu, I., and Talou, P.

Subjects

Nuclear Theory, Nuclear Experiment

Abstract

A major revision of the evaluation of $^{239}$Pu neutron-induced reaction cross sections is reported in the fast energy range. The evaluation starts at 2.5 keV incident neutron energy and has been extended up to 30 MeV. Several other notable changes are included in this evaluation since the release of ENDF/B-VIII.0 including the adoption of the Standards fission cross section, inclusion of new radiative capture data of Mosby et al., inclusion of the (n,2n) data of Meot et al., in addition to advances in the treatment of reaction modeling. In contrast to previous evaluation efforts, this evaluation is reproducible with detailed information stored chronologically utilizing a Git repository. The final evaluation results have been compiled into an ENDF-formatted file, which has been processed successfully through NJOY, checked for internal consistency, benchmarked versus older evaluations and validated against a suite of critical assemblies and pulsed-spheres., Comment: 31 pages, 31 figures, internal Los Alamos report

Published

2023

20. Consideration of memory of spin and parity in the fissioning compound nucleus by applying the Hauser-Feshbach fission fragment decay model to photonuclear reactions

Author

Kawano, Toshihiko, Lovell, Amy E., Okumura, Shin, Sasaki, Hirokazu, Stetcu, Ionel, and Talou, Patrick

Subjects

Nuclear Theory

Abstract

Prompt and $\beta$-delayed fission observables, such as the average number of prompt and delayed neutrons, the independent and cumulative fission product yields, and the prompt $\gamma$-ray energy spectra for the photonuclear reactions on $^{235,238}$U and $^{239}$Pu are calculated with the Hauser-Feshbach Fission Fragment Decay (HF$^3$D) model and compared with available experimental data. In the analysis of neutron-induced fission reactions to the case of photo-induced fission, an excellent reproduction of the delayed neutron yields supports a traditional assumption that the photo-fission might be similar to the neutron-induced fission at the same excitation energies regardless of the spin and parity of the fissioning systems.

Published

2022

21. Correlations between energy and $\gamma$-ray emission in $^{239}\mathrm{Pu}(n,\mathrm{f})$

Author

Giha, Nathan P., Marin, Stefano, Baker, James A., Hernandez, Isabel E., Kelly, Keegan J., Devlin, Matthew, O'Donnell, John M., Vogt, Ramona, Randrup, Jørgen, Talou, Patrick, Stetcu, Ionel, Lovell, Amy E., Litaize, Olivier, Serot, Olivier, Chebboubi, Abdelhazize, Wu, Ching-Yen, Clarke, Shaun D., and Pozzi, Sara A.

Subjects

Nuclear Experiment

Abstract

We study $\gamma$-ray emission following $^{239}\mathrm{Pu}(n,\mathrm{f})$ over an incident neutron energy range of $2 < E_i < 40$ MeV. We present the first experimental evidence for positive correlations between the total angular momentum generated in fission and the excitation energy of the compound nucleus prior to fission. The $\gamma$-ray multiplicity increases linearly with incident energy below the 2\textsuperscript{nd}-chance fission threshold with a slope of $0.085 \pm 0.010$ MeV$^{-1}$. This linear trend appears to hold for the average excitation energy of the compound nucleus between $9 < \langle E_x \rangle < 19$ MeV. Most of the multiplicity increase comes from an enhancement around a $\gamma$-ray energy of 0.7 MeV, which we interpret as stretched quadrupole $\gamma$ rays that indicate an increase in total fission-fragment angular momentum with excitation energy., Comment: 9 pages, 5 figures

Published

2022

22. Computational fluid dynamic modeling of the lymphatic system: a review of existing models and future directions

Author

Jayathungage Don, Tharanga D., Safaei, Soroush, Maso Talou, Gonzalo D., Russell, Peter S., Phillips, Anthony R. J., and Reynolds, Hayley M.

Published

2024

23. The CIELO collaboration: Progress in international evaluations of neutron reactions on Oxygen, Iron, Uranium and Plutonium

Author

Chadwick M.B., Capote R., Trkov A., Kahler A.C., Herman M.W., Brown D.A., Hale G.M., Pigni M., Dunn M., Leal L., Plompen A., Schillebeeck P., Hambsch F.-J., Kawano T., Talou P., Jandel M., Mosby S., Lestone J., Neudecker D., Rising M., Paris M., Nobre G.P.A., Arcilla R., Kopecky S., Giorginis G., Cabellos O., Hill I., Dupont E., Danon Y., Jing Q., Zhigang G., Tingjin L., Hanlin L., Xichao R., Haicheng W., Sin M., Bauge E., Romain P., Morillon B., Noguere G., Jacqmin R., Bouland O., De Saint Jean C., Pronyaev V.G., Ignatyuk A., Yokoyama K., Ishikawa M., Fukahori T., Iwamoto N., Iwamoto O., Kuneada S., Lubitz C.R., Palmiotti G., Salvatores M., Kodeli I., Kiedrowski B., Roubtsov D., Thompson I., Quaglioni S., Kim H.I., Lee Y.O., Koning A.J., Carlson A., Fischer U., and Sirakov I.

Subjects

Physics, QC1-999

Abstract

The CIELO collaboration has studied neutron cross sections on nuclides that significantly impact criticality in nuclear technologies – 16O, 56Fe, 235,8U and 239Pu – with the aim of improving the accuracy of the data and resolving previous discrepancies in our understanding. This multi-laboratory pilot project, coordinated via the OECD/NEA Working Party on Evaluation Cooperation (WPEC) Subgroup 40 with support also from the IAEA, has motivated experimental and theoretical work and led to suites of new evaluated libraries that accurately reflect measured data and also perform well in integral simulations of criticality.

Published

2017

24. A new evaluation of the neutron data standards

Author

Carlson A.D., Pronyaev V., Hale G.M., Zhenpeng C., Capote R., Duran I., Hambsch F.-J., Kawano T., Kunieda S., Mannhart W., Marcinkevicius B., Nelson R.O., Neudecker D., Noguere G., Paris M., Schillebeeckx P., Simakov S., Smith D.L., Talou P., Tao X., Trkov A., and Wallner A.

Subjects

Physics, QC1-999

Abstract

Evaluations are being done for the H(n,n), 6Li(n,t), 10B(n,αγ), 10B(n,α), C(n,n), Au(n,γ), 235U(n,f) and 238U(n,f) standard cross sections. Evaluations are also being done for data that are not traditional standards including: the Au(n,γ) cross section at energies below where it is considered a standard; reference cross sections for prompt gamma-ray production in fast neutron-induced reactions; reference cross sections for very high energy fission cross sections; the 235U thermal neutron fission spectrum and the 252Cf spontaneous fission neutron spectrum and the thermal constants.

Published

2017

25. The 235U prompt fission neutron spectrum measured by the Chi-Nu project at LANSCE

Author

Gomez J.A., Devlin M., Haight R.C., O'Donnell J.M., Lee H.Y., Mosby S.M., Taddeucci T.N., Kelly K.J., Fotiades N., Neudecker D., White M.C., Talou P., Rising M.E., Solomon C.J., Wu C.Y., Bucher B., Buckner M.Q., and Henderson R.A.

Subjects

Physics, QC1-999

Abstract

The Chi-Nu experiment aims to accurately measure the prompt fission neutron spectrum for the major actinides. At the Los Alamos Neutron Science Center (LANSCE), fission can be induced with neutrons ranging from 0.7 MeV and above. Using a two arm time-of-flight (TOF) technique, the fission neutrons are measured in one of two arrays: a 22-6Li glass array for lower energies, or a 54-liquid scintillator array for outgoing energies of 0.5 MeV and greater. Presented here are the collaboration's preliminary efforts at measuring the 235U PFNS.

Published

2017

26. Noise-specific denoising method with applications to high-frequency ultrasonic images

Author

Talou, Gonzalo D. Maso and Blanco, Pablo J.

Subjects

Electrical Engineering and Systems Science - Signal Processing

Abstract

Denoising is of utmost importance for the visualization and processing of images featuring low signal-to-noise ratio. Total variation methods are among the most popular techniques to perform this task improving the signal-to-noise ratio while preserving coherent intensity discontinuities. In this work, a novel method, termed maximum likelihood data, is proposed, endowing the total variation formulation with the capability to deal with noise-specific models and pre-processing stages for a certain image of interest. To do this, the data fidelity term is modified by means of a maximum likelihood estimator between the original and the denoised image. To assess the improvements of the proposed method with respect to the total variation formulation, we study the denoising of high-frequency ultrasonic images on in-silico and in-vivo setups. The proposed method delivered a better contrast, preservation and localization of the structures while diminishing the intensity bias of the total variation formulation for the multiplicative noise. The enhancement of medical images through denoising helps to improve the outcome of subsequently applied image processing such as registration and segmentation procedures.

Published

2022

27. QU-BraTS: MICCAI BraTS 2020 Challenge on Quantifying Uncertainty in Brain Tumor Segmentation - Analysis of Ranking Scores and Benchmarking Results

Author

Mehta, Raghav, Filos, Angelos, Baid, Ujjwal, Sako, Chiharu, McKinley, Richard, Rebsamen, Michael, Datwyler, Katrin, Meier, Raphael, Radojewski, Piotr, Murugesan, Gowtham Krishnan, Nalawade, Sahil, Ganesh, Chandan, Wagner, Ben, Yu, Fang F., Fei, Baowei, Madhuranthakam, Ananth J., Maldjian, Joseph A., Daza, Laura, Gomez, Catalina, Arbelaez, Pablo, Dai, Chengliang, Wang, Shuo, Reynaud, Hadrien, Mo, Yuan-han, Angelini, Elsa, Guo, Yike, Bai, Wenjia, Banerjee, Subhashis, Pei, Lin-min, AK, Murat, Rosas-Gonzalez, Sarahi, Zemmoura, Ilyess, Tauber, Clovis, Vu, Minh H., Nyholm, Tufve, Lofstedt, Tommy, Ballestar, Laura Mora, Vilaplana, Veronica, McHugh, Hugh, Talou, Gonzalo Maso, Wang, Alan, Patel, Jay, Chang, Ken, Hoebel, Katharina, Gidwani, Mishka, Arun, Nishanth, Gupta, Sharut, Aggarwal, Mehak, Singh, Praveer, Gerstner, Elizabeth R., Kalpathy-Cramer, Jayashree, Boutry, Nicolas, Huard, Alexis, Vidyaratne, Lasitha, Rahman, Md Monibor, Iftekharuddin, Khan M., Chazalon, Joseph, Puybareau, Elodie, Tochon, Guillaume, Ma, Jun, Cabezas, Mariano, Llado, Xavier, Oliver, Arnau, Valencia, Liliana, Valverde, Sergi, Amian, Mehdi, Soltaninejad, Mohammadreza, Myronenko, Andriy, Hatamizadeh, Ali, Feng, Xue, Dou, Quan, Tustison, Nicholas, Meyer, Craig, Shah, Nisarg A., Talbar, Sanjay, Weber, Marc-Andre, Mahajan, Abhishek, Jakab, Andras, Wiest, Roland, Fathallah-Shaykh, Hassan M., Nazeri, Arash, Milchenko1, Mikhail, Marcus, Daniel, Kotrotsou, Aikaterini, Colen, Rivka, Freymann, John, Kirby, Justin, Davatzikos, Christos, Menze, Bjoern, Bakas, Spyridon, Gal, Yarin, and Arbel, Tal

Subjects

Electrical Engineering and Systems Science - Image and Video Processing, Computer Science - Computer Vision and Pattern Recognition, Computer Science - Machine Learning

Abstract

Deep learning (DL) models have provided state-of-the-art performance in various medical imaging benchmarking challenges, including the Brain Tumor Segmentation (BraTS) challenges. However, the task of focal pathology multi-compartment segmentation (e.g., tumor and lesion sub-regions) is particularly challenging, and potential errors hinder translating DL models into clinical workflows. Quantifying the reliability of DL model predictions in the form of uncertainties could enable clinical review of the most uncertain regions, thereby building trust and paving the way toward clinical translation. Several uncertainty estimation methods have recently been introduced for DL medical image segmentation tasks. Developing scores to evaluate and compare the performance of uncertainty measures will assist the end-user in making more informed decisions. In this study, we explore and evaluate a score developed during the BraTS 2019 and BraTS 2020 task on uncertainty quantification (QU-BraTS) and designed to assess and rank uncertainty estimates for brain tumor multi-compartment segmentation. This score (1) rewards uncertainty estimates that produce high confidence in correct assertions and those that assign low confidence levels at incorrect assertions, and (2) penalizes uncertainty measures that lead to a higher percentage of under-confident correct assertions. We further benchmark the segmentation uncertainties generated by 14 independent participating teams of QU-BraTS 2020, all of which also participated in the main BraTS segmentation task. Overall, our findings confirm the importance and complementary value that uncertainty estimates provide to segmentation algorithms, highlighting the need for uncertainty quantification in medical image analyses. Finally, in favor of transparency and reproducibility, our evaluation code is made publicly available at: https://github.com/RagMeh11/QU-BraTS., Comment: Accepted for publication at the Journal of Machine Learning for Biomedical Imaging (MELBA): https://www.melba-journal.org/papers/2022:026.html

Published

2021

28. ENDFtk: A robust tool for reading and writing ENDF-formatted nuclear data

Author

Haeck, W., Gibson, N., and Talou, P.

Published

2024

29. Toward a New Evaluation of Neutron Standards

Author

Carlson A.D., Pronyaev V.G., Capote R., Hale G.M., Hambsch F.-J., Kawano T., Kunieda S., Mannhart W., Nelson R.O., Neudecker D., Schillebeeckx P., Simakov S., Smith D.L., Talou P., Tao X., Wallner A., and Wang W.

Subjects

Physics, QC1-999

Abstract

Measurements related to neutron cross section standards and certain prompt neutron fission spectra are being evaluated. In addition to the standard cross sections, investigations of reference data that are not as well known as the standards are being considered. Procedures and codes for performing this work are discussed. A number of libraries will use the results of this standards evaluation for new versions of their libraries. Most of these data have applications in neutron dosimetry.

Published

2016

30. Evaluating the 239Pu Prompt Fission Neutron Spectrum Induced by Thermal to 30 MeV Neutrons

Author

Neudecker D., Talou P., Kawano T., Kahler A.C., Rising M.E., and White M.C.

Subjects

Physics, QC1-999

Abstract

We present a new evaluation of the 239Pu prompt fission neutron spectrum (PFNS) induced by thermal to 30 MeV neutrons. Compared to the ENDF/B-VII.1 evaluation, this one includes recently published experimental data as well as an improved and extended model description to predict PFNS. For instance, the pre-equilibrium neutron emission component to the PFNS is considered and the incident energy dependence of model parameters is parametrized more realistically. Experimental and model parameter uncertainties and covariances are estimated in detail. Also, evaluated covariances are provided between all PFNS at different incident neutron energies. Selected evaluation results and first benchmark calculations using this evaluation are briefly discussed.

Published

2016

31. Neutron-induced fission: properties of prompt neutron and γ rays as a function of incident energy

Author

Stetcu I., Talou P., and Kawano T.

Subjects

Physics, QC1-999

Abstract

We have applied the Hauser-Feshbach statistical theory, in a Monte-Carlo implementation, to the de-excitation of fission fragments, obtaining a reasonable description of the characteristics of neutrons and gamma rays emitted before beta decays toward stability. Originally implemented for the spontaneous fission of 252Cf and the neutroninduced fission of 235U and 239Pu at thermal neutron energy, in this contribution we discuss the extension of the formalism to incident neutron energies up to 20 MeV. For the emission of pre-fission neutrons, at incident energies beyond second-chance fission, we take into account both the pre-equilibrium and statistical pre-fission components. Phenomenological parameterizations of mass, charge and TKE yields are used to obtain the initial conditions for the fission fragments that subsequently decay via neutron and emissions. We illustrate this approach for 239Pu(n,f).

Published

2016

32. Angular momentum removal by neutron and $\gamma$-ray emissions during fission fragment decays

Author

Stetcu, I., Lovell, A. E., Talou, P., Kawano, T., Marin, S., Pozzi, S. A., and Bulgac, A.

Subjects

Nuclear Theory, Nuclear Experiment

Abstract

We investigate the angular momentum removal from fission fragments (FFs) through neutron and $\gamma$-ray emission, where we find that about half the neutrons are emitted with angular momenta $\ge 1.5\hbar$ and that the change in angular momentum after the emission of neutrons and statistical $\gamma$ rays is significant, contradicting usual assumptions. Per fission event, in our simulations, the neutron and statistical $\gamma$-ray emissions change the spin of the fragment by 3.5 -- 5~$\hbar$, with a large standard deviation comparable to the average value. Such wide angular momentum removal distributions can hide any underlying correlations in the fission fragment initial spin values. Within our model, we reproduce data on spin measurements from discrete transitions after neutron emissions, especially in the case of light FFs. The agreement further improves for the heavy fragments if one removes from the analysis the events that would produce isomeric states. Finally, we show that while in our model the initial FF spins do not follow a saw-tooth like behavior observed in recent measurements, the average FF spin computed after neutron and statistical $\gamma$ emissions exhibits a shape that resembles a saw tooth. This suggests that the average FF spin measured after statistical emissions is not necessarily connected with the scission mechanism as previously implied., Comment: 9 pages, 6 figures; version accepted for publication

Published

2021

33. Current and Future Research at DANCE

Author

Jandel M., Baramsai B., Bredeweg T. A., Couture A., Hayes A., Kawano T., Mosby S., Rusev G., Stetcu I., Taddeucci T. N., Talou P., Ullmann J. L., Walker C. L., and Wilhelmy J. B.

Subjects

Physics, QC1-999

Abstract

An overview of the current experimental program on measurements of neutron capture and neutron induced fission at the Detector for Advanced Neutron Capture Experiments (DANCE) is presented. Three major projects are currently under way: 1) high precision measurements of neutron capture cross sections on Uranium isotopes, 2) research aimed at studies of the short-lived actinide isomer production in neutron capture on 235U and 3) measurements of correlated data of fission observables. New projects include developments of auxiliary detectors to improve the capability of DANCE. We are building a compact, segmented NEUtron detector Array at DANCE (NEUANCE), which will be installed in the central cavity of the DANCE array. It will provide experimental information on prompt fission neutrons in coincidence with the prompt fission gamma-rays measured by 160 BaF2 crystals of DANCE. Unique correlated data will be obtained for neutron capture and neutron-induced fission using the DANCE-NEUANCE experimental set up in the future.

Published

2015

34. Structure in the Event-by-Event Energy-Dependent Neutron-Gamma Multiplicity Correlations in $^{252}\text{Cf}$(sf)

Author

Marin, Stefano, Okar, Mustapha Stephan, Sansevero, Eoin P., Hernandez, Isabel E., Ballard, Catherine A., Vogt, Ramona, Randrup, Jørgen, Talou, Patrick, Lovell, Amy E., Stetcu, Ionel, Serot, Olivier, Litaize, Olivier, Chebboubi, Abdelhazize, Clarke, Shaun D., Protopopescu, Vladimir A., and Pozzi, Sara A.

Subjects

Nuclear Experiment, Nuclear Theory

Abstract

The emission of neutrons and gamma rays by fission fragments reveal important information about the properties of fragments immediately following scission. The initial fragment properties, correlations between fragments, and emission competition give rise to correlations in neutron-gamma emission. Neutron-gamma correlations are important in nonproliferation applications because the characterization of fissionable samples relies on the identification of signatures in the measured radiation. Furthermore, recent theoretical and experimental advances have proposed to explain the mechanism of angular momentum generation in fission. In this paper, we present a novel analysis method of neutrons and gamma rays emitted by fission fragments that allows us to discern structure in the observed correlations. We have analyzed data collected on \ce{^{252}Cf}(sf) at the Chi-Nu array at the Los Alamos Neutron Science Center. Through our analysis of the energy-differential neutron-gamma multiplicity covariance, we have observed enhanced neutron-gamma correlations, corresponding to rotational band gamma-ray transitions, at gamma-ray energies of $0.7$ and $1.2$ MeV. To shed light on the origin of this structure, we compare the experimental data with the predictions of three model calculations. The origin of the observed correlation structure is understood in terms of a positive spin-energy correlation in the generation of angular momentum in fission., Comment: 21 pages, 4 figures, 1 table

Published

2021

35. Influence of non-statistical properties in nuclear structure on emission of prompt fission neutrons

Author

Kawano, Toshihiko, Okumura, Shin, Lovell, Amy E., Stetcu, Ionel, and Talou, Patrick

Subjects

Nuclear Theory

Abstract

The Hauser-Feshbach Fission Fragment Decay (HF$^3$D) model is extended to calculate the prompt fission neutron spectrum (PFNS) for the thermal neutron induced fission on $^{235}$U, where the evaporated neutrons from all possible fission fragment pairs are aggregated. By studying model parameter sensitivities on the calculated PFNS, as well as non-statistical behavior of low-lying discrete level spin distribution, we conclude that discrepancies between the aggregation calculation and the experimental PFNS seen at higher neutron emission energies can be attributed to both the primary fission fragment yield distribution and the possible high spin states that are not predicted by the statistical theory of nuclear structure.

Published

2021

36. Contributions for ENDF/B-VIII.1 Paper

Author

Neudecker, D., primary, Kleedtke, N., additional, Kahler, A., additional, Casperson, R., additional, Lovell, A., additional, Gibson, N., additional, Marshall, W., additional, Parsons, K., additional, and Talou, P., additional

Published

2024

37. Recycling of hyoscyamine 6β-hydroxylase for the in vitro production of anisodamine and scopolamine

Author

Minoia, Juan M., Villanueva, María E., Copello, Guillermo J., Rodríguez Talou, Julián, and Cardillo, Alejandra B.

Published

2023

38. Fission Fragment Decay Simulations with the CGMF Code

Author

Talou, P., Stetcu, I., Jaffke, P., Rising, M. E., Lovell, A. E., and Kawano, T.

Subjects

Nuclear Theory

Abstract

The CGMF code implements the Hauser-Feshbach statistical nuclear reaction model to follow the de-excitation of fission fragments by successive emissions of prompt neutrons and $\gamma$ rays. The Monte Carlo technique is used to facilitate the analysis of complex distributions and correlations among the prompt fission observables. Starting from initial configurations for the fission fragments in mass, charge, kinetic energy, excitation energy, spin, and parity, $Y(A,Z,KE,U,J,\pi)$, CGMF samples neutron and $\gamma$-ray probability distributions at each stage of the decay process, conserving energy, spin and parity. Nuclear structure and reaction input data from the RIPL library are used to describe fission fragment properties and decay probabilities. Characteristics of prompt fission neutrons, prompt fission gamma rays, and independent fission yields can be studied consistently. Correlations in energy, angle and multiplicity among the emitted neutrons and $\gamma$ rays can be easily analyzed as a function of the emitting fragments.

Published

2020

39. Extension of the Hauser-Feshbach Fission Fragment Decay Model to Multi-Chance Fission

Author

Lovell, A. E., Kawano, T., Okumura, S., Stetcu, I., Mumpower, M. R., and Talou, P.

Subjects

Nuclear Theory, Nuclear Experiment

Abstract

The Hauser-Feshbach fission fragment decay model, $\mathtt{HF^3D}$, which calculates the statistical decay of fission fragments, has been expanded to include multi-chance fission, up to neutron incident energies of 20 MeV. The deterministic decay takes as input pre-scission quantities - fission probabilities and the average energy causing fission - and post-scission quantities - yields in mass, charge, total kinetic energy, spin, and parity. From these fission fragment initial conditions, the full decay is followed through both prompt and delayed particle emissions, allowing for the calculation of prompt neutron and $\gamma$ properties, such as multiplicity and energy distributions, both independent and cumulative fission yields, and delayed neutron observables. In this work, we describe the implementation of multi-chance fission into the $\mathtt{HF^3D}$ model, and show an example of prompt and delayed quantities beyond first-chance fission, using the example of neutron-induced fission on $^{235}$U. This expansion represents significant progress in consistently modeling the emission of prompt and delayed particles from fissile systems., Comment: 15 pages, 11 figures, submitted to PRC

Published

2020

40. Quantifying Uncertainties on Fission Fragment Mass Yields With Mixture Density Networks

Author

Lovell, A. E., Mohan, A. T., and Talou, P.

Subjects

Nuclear Theory, Nuclear Experiment

Abstract

Probabilistic machine learning techniques can learn both complex relations between input features and output quantities of interest as well as take into account stochasticity or uncertainty within a data set. In this initial work, we explore the use of one such probabilistic network, the Mixture Density Network (MDN), to reproduce fission yields and their uncertainties. We study mass yields for the spontaneous fission of $^{252}$Cf, exploring the number of training samples needed for converged predictions, how different levels of uncertainty propagate from the training set to the MDN predictions, and how well physical constraints of the yields - such as normalization and symmetry - are upheld by the algorithm. Finally, we test the ability of the MDN to interpolate between and extrapolate beyond samples in the training set using energy-dependent mass yields for the neutron-induced fission on $^{235}$U. The MDN provides a reliable way to include and predict uncertainties and is a promising path forward for supplementing sparse sets of nuclear data., Comment: 20 pages, 8 figures, submitted to J. Phys. G

Published

2020

41. Correlations Between Fission Fragment and Neutron Anisotropies in Neutron-Induced Fission

Author

Lovell, A. E., Talou, P., Stetcu, I., and Kelly, K. J.

Subjects

Nuclear Theory, Nuclear Experiment

Abstract

Several sources of angular anisotropy for fission fragments and prompt neutrons have been studied in neutron-induced fission reactions. These include kinematic recoils of the target from the incident neutron beam and the fragments from the emission of the prompt neutrons, preferential directions of the emission of the fission fragments with respect to the beam axis due to the population of particular transition states at the fission barrier, and forward-peaked angular distributions of pre-equilibrium neutrons which are emitted before the formation of a compound nucleus. In addition, there are several potential sources of angular anisotropies that are more difficult to disentangle: the angular distributions of prompt neutrons from fully accelerated fragments or from scission neutrons, and the emission of neutrons from fission fragments that are not fully accelerated. In this work, we study the effects of the first group of anisotropy sources, particularly exploring the correlations between the fission fragment anisotropy and the resulting neutron anisotropy. While kinematic effects were already accounted for in our Hauser-Feshbach Monte Carlo code, $\mathtt{CGMF}$, anisotropic angular distributions for the fission fragments and pre-equilibrium neutrons resulting from neutron-induced fission on $^{233,234,235,238}$U, $^{239,241}$Pu, and $^{237}$Np have been introduced for the first time. The effects of these sources of anisotropy are examined over a range of incident neutron energies, from thermal to 20 MeV, and compared to experimental data from the Chi-Nu liquid scintillator array. The anisotropy of the fission fragments is reflected in the anisotropy of the prompt neutrons, especially as the outgoing energy of the prompt neutrons increases, allowing for an extraction of the fission fragment anisotropy to be made from a measurement of the neutrons., Comment: 10 pages, 7 figures, submitted to Phys. Rev. C

Published

2020

42. Monte Carlo Simulation for Statistical Decay of Compound Nucleus

Author

Chadwick M.B., Talou P., and Kawano T.

Subjects

Physics, QC1-999

Abstract

We perform Monte Carlo simulations for neutron and γ-ray emissions from a compound nucleus based on the Hauser-Feshbach statistical theory. This Monte Carlo Hauser-Feshbach (MCHF) method calculation, which gives us correlated information between emitted particles and γ-rays. It will be a powerful tool in many applications, as nuclear reactions can be probed in a more microscopic way. We have been developing the MCHF code, CGM, which solves the Hauser-Feshbach theory with the Monte Carlo method. The code includes all the standard models that used in a standard Hauser-Feshbach code, namely the particle transmission generator, the level density module, interface to the discrete level database, and so on. CGM can emit multiple neutrons, as long as the excitation energy of the compound nucleus is larger than the neutron separation energy. The γ-ray competition is always included at each compound decay stage, and the angular momentum and parity are conserved. Some calculations for a fission fragment 140Xe are shown as examples of the MCHF method, and the correlation between the neutron and γ-ray is discussed.

Published

2012

43. Structure in the event-by-event energy-dependent neutron-gamma multiplicity correlations in Cf-252(sf)

Author

Marin, Stefano, Okar, M Stephan, Sansevero, Eoin P, Hernandez, Isabel E, Ballard, Catherine A, Vogt, Ramona, Randrup, Jorgen, Talou, Patrick, Lovell, Amy E, Stetcu, Ionel, Serot, Olivier, Litaize, Olivier, Chebboubi, Abdelhazize, Clarke, Shaun D, Protopopescu, Vladimir A, and Pozzi, Sara A

Published

2021

44. Structure in the event-by-event energy-dependent neutron-γ multiplicity correlations in Cf252(sf)

Author

Marin, Stefano, Okar, M Stephan, Sansevero, Eoin P, Hernandez, Isabel E, Ballard, Catherine A, Vogt, Ramona, Randrup, Jørgen, Talou, Patrick, Lovell, Amy E, Stetcu, Ionel, Serot, Olivier, Litaize, Olivier, Chebboubi, Abdelhazize, Clarke, Shaun D, Protopopescu, Vladimir A, and Pozzi, Sara A

Subjects

Nuclear and Plasma Physics, Synchrotrons and Accelerators, Physical Sciences, Nuclear and plasma physics

Abstract

The emission of neutrons and γ rays by fission fragments reveal important information about the properties of fragments immediately following scission. The initial fragment properties, correlations between fragments, and emission competition give rise to correlations in neutron-γ emission. Recent theoretical and experimental advances have been proposed to explain the mechanism of angular momentum generation in fission, which would result in observable signature in neutron-γ emission correlations. In this paper, we present a novel analysis method of neutrons and γ rays emitted by fission fragments that allows us to discern structure in the observed correlations. We have analyzed data collected on Cf252(sf) at the Chi-Nu array at the Los Alamos Neutron Science Center. Through our analysis of the energy-differential neutron-γ multiplicity covariance, we have observed enhanced neutron-γ correlations, corresponding to rotational band γ-ray transitions, at γ-ray energies of 0.7 and 1.2 MeV. To shed light on the origin of this structure, we compare the experimental data with the predictions of three model calculations. The origin of the observed correlation structure is understood in terms of a positive spin-energy correlation in the generation of angular momentum in fission.

Published

2021

45. Advanced Modeling of Prompt Fission Neutrons and Gamma Rays

Author

Kawano T. and Talou P.

Subjects

Physics, QC1-999

Abstract

Prompt fission neutrons and gamma rays are computed using a Monte Carlo treatment of the statistical evaporation of the excited primary fission fragments. The assumption of two fragments in thermal equilibrium at the time of neutron emission is addressed by studying the neutron multiplicity as a function of fragment mass. Results for the neutron-induced fission of 235U are discussed, for incident neutron energies from 0.5 to 5.5 MeV. Recent experimental data on the fission fragment yields as a function of mass and total kinetic energy are used as input data.

Published

2010

46. Recent Advances in Modeling Fission Cross Sections over Intermediate Structures

Author

Bouland O., Eric Lynn J.E., and Talou P.

Subjects

Physics, QC1-999

Abstract

More accurate fission cross section calculations in presence of underlying intermediate structure are strongly desired. This paper recalls the common approximations used below the fission threshold and quantifies their impact. In particular, an exact expanded R-matrix Monte Carlo calculation of the intermediate structure, deeply mixed with the fluctuations of the class-I and II decay amplitudes, is shown. This paper also insists on the microscopic structure of the level densities as a function of the nucleus deformation and show preliminary neutron induced fission cross section calculations for 239Pu and 240Pu using newly calculated combinatorial level densities. Comparisons with recent evaluated and measured fission cross sections are made.

Published

2010

47. Monte Carlo simulation for statistical Hauser-Feshbach theory

Author

Watanabe T., Chadwick M.B., Talou P., and Kawano T.

Subjects

Physics, QC1-999

Abstract

Monte Carlo simulations for particle and γ-ray emissions from a compound nucleus based on the Hauser-Feshbach statistical theory are performed. The Monte Carlo method is applied to the neutron induced nuclear reactions on 56Fe, and the results are compared with a traditional deterministic method. The neutron and γ-ray emission correlation is examined by gating on an 847 ke γ-ray that is produced by an inelastic scattering process. The partial γ-ray energy spectra for different γ-ray multiplicities is inferred using this Monte Carlo method.

Published

2010

48. High-temperature mechanical behavior of partially sintered ceramics

Author

Nečina, Vojtěch, Gass, Sebastián E., Uhlířová, Tereza, Talou, Mariano H., Camerucci, M. Andrea, and Tomba Martinez, Analía G.

Published

2023

49. Event-by-Event Multiplicity Correlations in $^{252}$Cf(sf)

Author

Marin, Stefano, Protopopescu, Vladimir A., Vogt, Ramona, Marcath, Matthew J., Okar, M. Stephan, Hua, Michael Y., Talou, Patrick, Schuster, Patricia F., Clarke, Shaun D., and Pozzi, Sara A.

Subjects

Nuclear Experiment, Nuclear Theory

Abstract

Excited nuclear fragments are emitted during nuclear fission. The de-excitation of these fission fragments takes place as sequential emission of neutrons followed by photons. A correlation between neutron and photon multiplicities accompanying fission is thus expected. Fission event generators based on established statistical nuclear physics models predict a negative event-by-event correlation in neutron-photon multiplicity. A survey of published experimental results of an event-by-event covariance between the neutron and photon multiplicities emitted following the spontaneous fission of $^{252}$Cf is presented. Analytic unfolding expressions are developed in this work to determine the bias introduced by background sources, particle misclassification, pulse pileup, and inelastic photon production. The published experimental data are re-analyzed using these unfolding techniques and are found to be in qualitative agreement with the predictions of model-based calculations. In particular, we have concluded that there exists a significant event-by-event neutron-photon emission competition following the spontaneous fission of $^{252}$Cf., Comment: 8pages, 3 figures, 2 table

Published

2019

50. Prompt Neutron Multiplicity Distributions Inferred from $\gamma$-ray and Fission Fragment Energy Measurements

Author

Lovell, A. E., Stetcu, I., Talou, P., Rusev, G., and Jandel, M.

Subjects

Nuclear Theory, Nuclear Experiment

Abstract

We propose a novel method to extract the prompt neutron multiplicity distribution, $P(\nu)$, in fission reactions based on correlations between prompt neutrons, $\gamma$ rays, and fragment kinetic energy arising from energy conservation. In this approach, only event-by-event measurements of the total $\gamma$-ray energy released as a function of the total kinetic energy (TKE) of the fission fragments are performed, and no neutron detection is required. Using the $\texttt{CGMF}$ fission event generator, we illustrate the method and explore the accuracy of extracting the neutron multiplicity distribution when taking into account the energy resolution and calibration of the energy measurements. We find that a TKE resolution of under 2 MeV produces reasonably accurate results, independent of typical $\gamma$-ray energy measurement resolution., Comment: 5 pages, 4 figures, published in PRC

Published

2019