Your search keyword '"Damian, J. I. Marquez"' showing total 11 results

1. The HIBEAM program: search for neutron oscillations at the ESS

Author

Santoro, V., Milstead, D., Fierlinger, P., Snow, W. M., Barrow, J., Bartis, M., Bentley, P., Björk, L., Brooijmans, G., de la Cour, N., Di Julio, D. D., Dunne, K., Eriksson, H., Ferreira, M. J., Friman-Gayer, U., Holl, M., Kamyshkov, Y., Kemp, E., Kickulies, M., Kolevatov, R., Johansson, H. T., Jönsson, B., Lejon, W., Damian, J. I. Marquez, Meirose, B., Nepomuceno, A., Nilsson, T., Oskarsson, A., Pasechnik, R., Persson, L. B., Rataj, B., Rogers, J., Silverstein, S., Stadnik, Y. V., Wagner, R., Wolker, M., Yiu, S. C., and Zanini, L.

Subjects

Physics - Instrumentation and Detectors

Abstract

With the construction of the European Spallation Source, a remarkable opportunity has emerged to conduct high sensitivity searches for neutron oscillations, including a first search for thirty years for free neutrons converting to antineutrons. Furthermore, searches can be made for transitions of neutrons and antineutrons to sterile neutron states. Upgrades to the ESS infrastructure allow an improved HIBEAM design that would provide an increase in sensitivity by an order of magnitude compared to previous work. The HIBEAM program focuses on processes that violate baryon number by one or two units. The observation of a process satisfying one of the Sakharov conditions addresses the open question of the origin of the matter-antimatter asymmetry in the Universe. Sterile neutron states would belong to a `dark' sector of particles which may explain dark matter. As electrically neutral, meta-stable objects that can be copiously produced and studied, neutrons represent an attractive portal to a `dark' sector. The HIBEAM instrument can also be utilised for other purposes such as direct searches for ultralight axion dark matter. This paper describes the capability, design, infrastructure, and potential of the HIBEAM program. This includes a dedicated beamline, neutron optical system, magnetic shielding and control, and detectors for neutrons and antineutrons., Comment: 58 pages, 23 figures

Published

2023

2. HighNESS Conceptual Design Report: Volume I

Author

Santoro, V., Kheir, O. Abou El, Acharya, D., Akhyani, M., Andersen, K. H., Barrow, J., Bentley, P., Bernasconi, M., Bertelsen, M., Bessler, Y., Bianchi, A., Brooijmans, G., Broussard, L., Brys, T., Busi, M., Campi, D., Chambon, A., Chen, J., Czamler, V., Deen, P., DiJulio, D. D., Dian, E., Draskovits, L., Dunne, K., Barbari, M. El, Ferreira, M. J., Fierlinger, P., Fröst, V. T., Folsom, B. T., Friman-Gayer, U., Gaye, A., Gorini, G., Gustafsson, A., Gutberlet, T., Happe, C., Han, X., Hartl, M., Holl, M., Jackson, A., Kemp, E., Kamyshkov, Y., Kittelmann, T., Klinkby, E. B., Kolevatov, R., Laporte, S. I., Lauritzen, B., Lejon, W., Linander, R., Lindroos, M., Marko, M., Damián, J. I. Márquez, McClanahan, T. C., Meirose, B., Mezei, F., Michel, K., Milstead, D., Muhrer, G., Nepomuceno, A., Neshvizhevsky, V., Nilsson, T., Odén, U., Plivelic, T., Ramic, K., Rataj, B., Remec, I., Rizzi, N., Rogers, J., Rosenthal, E., Rosta, L., Rücker, U., Samothrakitis, S., Schreyer, A., Selknaes, J. R., Shuai, H., Silverstein, S., Snow, W. M., Strobl, M., Strothmann, M., Takibayev, A., Wagner, R., Willendrup, P., Xu, S., Yiu, S. C., Yngwe, L., Young, A. R., Wolke, M., Zakalek, P., Zavorka, L., Zanini, L., and Zimmer, O.

Subjects

Physics - Instrumentation and Detectors

Abstract

The European Spallation Source, currently under construction in Lund, Sweden, is a multidisciplinary international laboratory. Once completed to full specifications, it will operate the world's most powerful pulsed neutron source. Supported by a 3 million Euro Research and Innovation Action within the EU Horizon 2020 program, a design study (HighNESS) has been completed to develop a second neutron source located below the spallation target. Compared to the first source, designed for high cold and thermal brightness, the new source has been optimized to deliver higher intensity, and a shift to longer wavelengths in the spectral regions of cold (CN, 2--20\,\AA), very cold (VCN, 10--120\,\AA), and ultracold (UCN, ${>}\,{500}$\,\AA) neutrons. The second source comprises a large liquid deuterium moderator designed to produce CN and support secondary VCN and UCN sources. Various options have been explored in the proposed designs, aiming for world-leading performance in neutronics. These designs will enable the development of several new instrument concepts and facilitate the implementation of a high-sensitivity neutron-antineutron oscillation experiment (NNBAR). This document serves as the Conceptual Design Report for the HighNESS project, representing its final deliverable., Comment: 269 pages, 255 figures. Volume I of the final deliverable of the HighNESS Project (HORIZON 2020 grant agreement ID: 951782)

Published

2023

3. Spectroscopic Neutron Imaging for Resolving Hydrogen Dynamics Changes in Battery Electrolytes

Author

Ruiz, E. R. Carreón, Lee, J., Damián, J. I. Márquez, Strobl, M., Burca, G., Woracek, R., Cochet, M., Ebert, M. -O., Höltschi, L., Kadletz, P. M., Tremsin, A. S., Winter, E., Zlobinski, M., Gubler, L., and Boillat, P.

Subjects

Condensed Matter - Materials Science, Physics - Chemical Physics

Abstract

We present spectroscopic neutron imaging (SNI), a bridge between imaging and scattering techniques, for the analysis of hydrogenated molecules in lithium-ion cells. The scattering information of CHn-based organic solvents and electrolytes was mapped in two-dimensional space by investigating the wavelength-dependent property of hydrogen atoms through time-of-flight imaging. Our investigation demonstrates a novel approach to detect physical and chemical changes in hydrogenated liquids, which extends, but not limits, the use of SNI to relevant applications in electrochemical devices, e.g., the study of electrolytes in Li-ion batteries.

Published

2022

4. Development of a High Intensity Neutron Source at the European Spallation Source: The HighNESS project

Author

Santoro, V., Andersen, K. H., Bernasconi, M., Bertelsen, M., Beßler, Y., Campi, D., Czamler, V., Di Julio, D. D., Diane, E., Dunne, K., Fierlinger, P., Gaye, A., Gorini, G., Happe, C., Kittelmann, T., Klinkby, E. B., Kokai, Z., Kolevatov, R., Lauritzen, B., Linander, R., Damian, J. I. Marquez, Meirose, B., Mezei, F., Milstead, D., Muhrer, G., Ramic, K., Rataj, B., Rizzi, N., Samothrakitis, S., Selknaes, J. R., Silverstein, S., Strobl, M., Strothmann, M., Takibayev, A., Wagner, R., Willendrup, P., Yiu, S. -C., Zanini, L., and Zimmer, O.

Subjects

Physics - Instrumentation and Detectors, Condensed Matter - Other Condensed Matter, High Energy Physics - Experiment

Abstract

The European Spallation Source (ESS), presently under construction in Lund, Sweden, is a multidisciplinary international laboratory that will operate the world's most powerful pulsed neutron source. Supported by a 3M Euro Research and Innovation Action within the EU Horizon 2020 program, a design study (HighNESS) is now underway to develop a second neutron source below the spallation target. Compared to the first source, located above the spallation target and designed for high cold and thermal brightness, the new source will provide higher intensity, and a shift to longer wavelengths in the spectral regions of cold (2 /- 20 {\AA}), very cold (VCN, 10 /- 120 {\AA}), and ultra cold (UCN, > 500 {\AA}) neutrons. The core of the second source will consist of a large liquid deuterium moderator to deliver a high flux of cold neutrons and to serve secondary VCN and UCN sources, for which different options are under study. The features of these new sources will boost several areas of condensed matter research and will provide unique opportunities in fundamental physics. Part of the HighNESS project is also dedicated to the development of future instruments that will make use of the new source and will complement the initial suite of instruments in construction at ESS. The HighNESS project started in October 2020. In this paper, the ongoing developments and the results obtained in the first year are described., Comment: 10 pages, 10 figures, 14th International Topical Meeting on Nuclear Applications of Accelerators, November 30 to December 4, 2021, Washington, DC

Published

2022

5. KDSource, a tool for the generation of Monte Carlo particle sources using kernel density estimation

Author

Schmidt, N. S., Abbate, O. I., Prieto, Z. M., Robledo, J. I., Damián, J. I. Márquez, Márquez, A. A., and Dawidowski, J.

Subjects

Physics - Instrumentation and Detectors, Physics - Data Analysis, Statistics and Probability

Abstract

Monte Carlo radiation transport simulations have clearly contributed to improve the design of nuclear systems. When performing in-beam or shielding simulations a complexity arises due to the fact that particles must be tracked to regions far from the original source or behind the shielding, often lacking sufficient statistics. Different possibilities to overcome this problem such as using particle lists or generating synthetic sources have already been reported. In this work we present a new approach by using the adaptive multivariate kernel density estimator (KDE) method. This concept was implemented in KDSource, a general tool for modelling, optimizing and sampling KDE sources, which provides a convenient user interface. The basic properties of the method were studied in an analytical problem with a known density distribution. Furthermore, the tool was used in two Monte Carlo simulations that modelled neutron beams, which showed good agreement with experimental results.

Published

2022

6. Thermal neutron cross sections of amino acids from average contributions of functional groups

Author

Romanelli, G., Onorati, D., Ulpiani, P., Cancelli, S., Perelli-Cippo, E., Damián, J. I. Márquez, Capelli, S. C., Croci, G., Muraro, A., Tardocchi, M., Gorini, G., Andreani, C., and Senesi, R.

Subjects

Physics - Chemical Physics

Abstract

The experimental thermal neutron cross sections of the twenty proteinogenic amino acids have been measured over the incident-neutron energy range spanning from 1 meV to 10 keV and data have been interpreted using the multi-phonon expansion based on first-principles calculations. The scattering cross section, dominated by the incoherent inelastic contribution from the hydrogen atoms, can be rationalised in terms of the average contributions of different functional groups, thus neglecting their correlation. These results can be used for modelling the total neutron cross sections of complex organic systems like proteins, muscles, or human tissues from a limited number of starting input functions. This simplification is of crucial importance for fine-tuning of transport simulations used in medical applications, including boron neutron capture therapy as well as secondary neutrons-emission induced during proton therapy. Moreover, the parametrized neutron cross sections allow a better treatment of neutron scattering experiments, providing detailed sample self-attenuation corrections for a variety of biological and soft-matter systems.

Published

2021

7. Rejection-based sampling of inelastic neutron scattering

Author

Cai, X. X., Kittelmann, T., Klinkby, E., and Damián, J. I. Márquez

Subjects

Physics - Computational Physics

Abstract

Distributions of inelastically scattered neutrons can be quantum dynamically described by a scattering kernel. We present an accurate and computationally efficient rejection method for sampling a given scattering kernel of any isotropic material. The proposed method produces continuous neutron energy and angular distributions, typically using just a single interpolation per sampling. We benchmark the results of this method against those from accurate analytical models and one of the major neutron transport codes. We also show the results of applying this method to the conventional discrete double differential cross sections.

Published

2018

8. The HighNESS Project at the European Spallation Source : Current Status and Future Perspectives

Author

Santoro, V., Andersen, K. H., Bentley, P., Bernasconi, M., Bertelsen, M., Bessler, Y., Bianchi, A., Brys, T., Campi, D., Chambon, A., Czamler, V., Di Julio, D. D., Dian, E., Dunne, Katherine, Ferreira, M. J., Fierlinger, P., Friman-Gayer, U., Folsom, B. T., Gaye, A., Gorini, G., Happe, C., Holl, M., Kamyshkov, Y., Kittelmann, T., Klinkby, E. B., Kolevatov, R., Laporte, S. I., Lauritzen, B., Damian, J. I. Marquez, Meirose, Bernhard, Mezei, F., Milstead, David A., Muhrer, G., Neshvizhevsky, V., Rataj, B., Rizzi, N., Rosta, L., Samothrakitis, S., Schober, H., Selknaes, J. R., Silverstein, Samuel B., Strobl, M., Strothmann, M., Takibayev, A., Wagner, R., Willendrup, P., Xu, S., Yiu, S. C., Zanini, L., Zimmer, O., Santoro, V., Andersen, K. H., Bentley, P., Bernasconi, M., Bertelsen, M., Bessler, Y., Bianchi, A., Brys, T., Campi, D., Chambon, A., Czamler, V., Di Julio, D. D., Dian, E., Dunne, Katherine, Ferreira, M. J., Fierlinger, P., Friman-Gayer, U., Folsom, B. T., Gaye, A., Gorini, G., Happe, C., Holl, M., Kamyshkov, Y., Kittelmann, T., Klinkby, E. B., Kolevatov, R., Laporte, S. I., Lauritzen, B., Damian, J. I. Marquez, Meirose, Bernhard, Mezei, F., Milstead, David A., Muhrer, G., Neshvizhevsky, V., Rataj, B., Rizzi, N., Rosta, L., Samothrakitis, S., Schober, H., Selknaes, J. R., Silverstein, Samuel B., Strobl, M., Strothmann, M., Takibayev, A., Wagner, R., Willendrup, P., Xu, S., Yiu, S. C., Zanini, L., and Zimmer, O.

Abstract

The European Spallation Source (ESS), presently under construction in Lund, Sweden, is a multidisciplinary international laboratory that, once completed at full specifications, will operate the world's most powerful pulsed neutron source. Supported by a 3 M Euro Research and Innovation Action within the European Union Horizon 2020 program, a design study (HighNESS) is now underway to develop a second neutron source located below the spallation target. Compared to the first source, which is located above the spallation target and designed for high cold and thermal brightness, the new source is being optimized to deliver higher intensity and a shift to longer wavelengths in the spectral regions of cold neutrons (CNs) (2 to 20 & Aring;), very cold neutrons (VCNs) (10 to 120 & Aring;), and ultracold neutrons (UCNs) (> 500 & Aring;). The second source consists of a large liquid deuterium moderator to deliver CNs and serve secondary VCN and UCN sources, for which different options are under study. These new sources will boost several areas of condensed matter research and will provide unique opportunities in fundamental physics. The HighNESS project is now entering its last year, and we are working toward the Conceptual Design Report of the ESS upgrade. In this paper, results obtained in the first 2 years, ongoing developments, and future perspectives are described.

Published

2024

9. Very cold and ultra cold neutron sources for ESS.

Author

Zanini, L., Dian, E., DiJulio, D. D., Folsom, B., Klinkby, E. B., Kokai, Z., Damian, J. I. Marquez, Rataj, B., Rizzi, N., Santoro, V., Strothmann, M., Takibayev, A., Wagner, R. ., and Zimmer, O.

Subjects

NEUTRON sources, NEUTRON beams, ANGULAR distance, NEUTRONS, DEUTERIUM, SUPERFLUIDITY, NEUTRON generators

Abstract

The goal of the "Workshop on Very Cold and Ultra Cold Neutron Sources for ESS" was to discuss scientific cases, ideas and possibilities for the implementation of sources of Very Cold and Ultra Cold neutrons at the European Spallation Source. The ESS facility, presently under construction, offers several possibilities for in-pile UCN or VCN sources, in primis thanks to the available space below the spallation target where additional neutron sources can be placed to complement those above the target. Neutron beams can be extracted over a wide angular range with a grid of forty-two beamports with 6° average angular separation, allowing future instruments to be installed which may view either the upper or lower moderator systems. Of greatest interest for fundamental physics is the so-called Large Beamport foreseen for the NNBAR experiment. This beamport is also particularly well suited to feed a UCN source, for which several ideas were presented that employ either superfluid helium or solid deuterium as established neutron converter materials. Concepts for VCN sources make use of novel materials for VCN production and/or advanced reflectors to increase yields in the coldest part of the neutron spectrum from a cryogenic neutron source. In this paper we discuss these ideas and the possible locations of UCN and VCN sources at ESS. [ABSTRACT FROM AUTHOR]

Published

2022

10. Vibrational spectra of light and heavy water with application to neutron cross section calculations

Author

Damian, J. I. Marquez, primary, Malaspina, D. C., additional, and Granada, J. R., additional

Published

2013

11. Neutron Cross Sections Libraries for Methane in Phase II and Solid Deuterium

Author

Granada, J. R., primary, Cantargi, F., additional, and Damian, J. I. Marquez, additional

Published

2011