Your search keyword '"PARTICLE detectors"' showing total 3,690 results

1. On the physical origin of the superconducting transition in transition-edge sensors.

Author

Fàbrega, Lourdes, Camón, Agustín, Pobes, Carlos, and Strichovanec, Pavel

Subjects

*PARTICLE detectors, *NUCLEAR counters, *DETECTORS, *NOISE, *GEOMETRY

Abstract

Transition-Edge Sensors (TESs) constitute highly sensitive particle and radiation detectors, widely used in many applications. Each of these requires optimization of TES performances and designs, including sizes and geometries. These may have implications on the superconducting transition mechanisms and, therefore, on TESs performances and stability, through the specific shape of the resistance vs temperature and current R(T,I) and the nature of noise. In this study, we investigate the dependence of the superconducting transition, characterized by R(T,I), on TES size and bias current density. Through analyses of R(T,I) in bare Mo/Au TESs with Tc tuned for this study, we observe how the weak link behavior induced by the superconducting leads weakens and disappears as TES length or driving current increase, being substituted by another dominant transition mechanism, which might be related to a Berezinskii–Kosterlitz–Thouless transition. We also observe a significant broadening of the transition's upper part, attributed to the longitudinal proximity effect induced by the pads; for the shorter devices, this effect is observed for R > 70% Rn and results in TES resistances considerably lower than Rn up to temperatures well above the TES transition: R < Rn up to 3 K for a 8 μm-long device. [ABSTRACT FROM AUTHOR]

Published

2024

2. Fusion neutron source and array of particle detectors for nondestructive interrogation of special nuclear materials.

Author

Masuda, Kai, Takahashi, Yoshiyuki, Misawa, Tsuyoshi, Yamakawa, Norio, Scott, Thomas B., and Bakr, Mahmoud

Subjects

*PARTICLE detectors, *THRESHOLD energy, *NEUTRON temperature, *NEUTRON sources, *RADIOACTIVE substances, *NEUTRON generators

Abstract

Presented herein are the outcomes of an experimental test involving a pioneering portable-active interrogation system designed for the nondestructive detection of special nuclear materials (SNMs). The system relies on the threshold energy neutron analysis concept and incorporates a portable deuterium–deuterium (DD) neutron generator producing a particle intensity of 5 × 107 n/s, coupled with three arrays of tensioned metastable fluid detectors (TMFDs) to detect secondary neutrons from the fissile material. In the presence of the fissile material, prompt fission neutrons are emitted, with an average energy of approximately 2 MeV, and around 30% of these neutrons have energies above that of the DD neutron source (2.45 MeV). The detection of a statistically significant neutron population exceeding this threshold firmly indicates the presence of SNM. TMFDs exhibit high sensitivity in efficiently detecting neutrons above the threshold while adeptly discriminating against neutrons below the threshold as well as gamma rays. This unique feature allows the interrogation system to maintain a lightweight profile without necessitating substantial shielding materials. The validation experiments involved the placement of 70 or 140 g masses of U-235 within a 1 m3 inspection volume. Measurements were carried out over 30 min intervals, repeated numerous times, both with and without U-235, at a DD neutron source intensity of 8 × 105 n/sec. Experimental count rates with natural uranium (NU) are consistently above those without NU. The probability of detection (PD) and probability of false alarm (PFA) were assessed utilizing these count rates. The DD neutron source intensity and inspection time were normalized at 5 × 107 n/sec and 90 s, respectively. The results indicated a PD of approximately 74% and 98% for detecting 70 and 140 g of U-235, respectively, with a PFA of <5%. These promising outcomes align with the specified PD (>90%) and PFA (<5%) targets outlined in ANSI standards. [ABSTRACT FROM AUTHOR]

Published

2024

3. Where quantum weirdness hides.

Author

Rivlin, Tom

Subjects

*BOHMIAN mechanics, *PHYSICAL laws, *QUANTUM thermodynamics, *QUANTUM theory, *PARTICLE detectors

Abstract

The article explores the question of how quantum particles, which exist in multiple states simultaneously, give rise to the solid, well-defined world we experience. The author suggests that the answer may lie in the principles of thermodynamics, specifically the process of equilibration. They propose the measurement-equilibration hypothesis (MEH), which describes measurement as a process where quantum information spreads into the measuring device, making the classical information available to read while hiding the quantum behavior. The article discusses the implications of this hypothesis and the potential for future experiments to test its validity. [Extracted from the article]

Published

2024

4. The Neutral Water Torus of Europa.

Author

Nénon, Q. and Leblanc, F.

Subjects

*MONTE Carlo method, *EUROPA (Satellite), *SPACE environment, *PARTICLE detectors, *JUPITER (Planet)

Abstract

The neutral particles that escape Europa form a neutral torus which asymmetrically encircles the giant planet Jupiter. The study of this structure can inform on neutral escape at the icy moon and on the loading of the Jovian magnetosphere with Europan material. In this letter, we present the first Monte Carlo model of the neutral water torus of Europa. Water molecules are released to high altitude by ion sputtering of the surface and get dissociated and ionized mostly by electron impact. We find that the density of H2O molecules can be as large as atomic O in a large region of the Jovian magnetosphere. The neutral torus of Europa may therefore have a more diverse composition than previously thought. Plasma instrumentation able to separate H2O+ from O+ pick‐up ions could help to advance our understanding of the neutral torus of Europa. Plain Language Summary: The surface of the Galilean moon Europa is covered of water ice. The interaction of the icy surface with the space environment ejects water molecules in space, some of which are fast enough to escape the gravity of Europa but remain trapped by the gravity of the gas giant planet. The liberated water molecules therefore encircle Jupiter at the orbital distance of Europa in a torus‐shaped structure. In this letter, we present the first three‐dimensional model of the water torus generated by Europa around Jupiter. We find that the density of water molecules can be as large as that of oxygen atoms modeled in previous work, thereby indicating that water can be a dominant species of the Europa‐generated neutral torus. Beyond models, the study of the Europa torus would require sophisticated particle detectors onboard a mission in the Jovian system. Key Points: First Monte Carlo model of the neutral H2O torus of EuropaIon sputtering of the surface is the source of water for the torusWater can be a dominant species of the neutral torus [ABSTRACT FROM AUTHOR]

Published

2024

5. Investigating the average kiloelectron-volt emission of partially observed events in nuclear physics through distance weighted mean based censored control chart.

Author

Nisar, Shumaila, Raza, Syed Muhammad Muslim, Albalawi, Olayan, and Alharthi, Aiedh Mrisi

Subjects

*PARTICLE detectors, *NUCLEAR physics, *CENSORING (Statistics), *RESEARCH personnel, *DECISION making, *QUALITY control charts, *CUSUM technique

Abstract

The average lifespan of particles, a crucial parameter in nuclear physics, is essential for identification purposes. Modern particle detectors excel at recognizing individual radioactive nuclei arrivals and their subsequent decay events. However, challenges arise when matching arrivals with departures, especially when departures are only partially observed. One inefficient approach involves conducting experiments with very low arrival rates to facilitate matching. The kiloelectron-volt E(keV) emission is obtained during this radio active process. This study focuses on the meticulous surveillance of the average keV emission from partially observed events within the domain of nuclear physics. To accomplish this, the methodology employs the statistical approach known as Distance Weighted Mean (DWM), integrated with the application of censored control charts. The utilization of censored control charts allows for the effective management of incomplete data, enabling researchers to make informed decisions despite potential limitations in observation. We propose a DWM based exponentially weighted moving average-cumulative sum (DWM-EC) control chart for monitoring kiloelectron-volt E(keV) data. The proposed charts is developed for Weibull lifetimes under type-I censoring. For the construction of an efficient control charting structure, we employed the conditional median (CM) methods. The goal is to find changes in the mean of Weibull lifetimes with censored data with known and estimated parameter conditions. The performance of the proposed DWM-EC chart is evaluated by the average run length (ARL). Besides a simulation study, a real-life data set on E(keV) related to the alpha decays of 177 Lutetium isotope is also discussed. [ABSTRACT FROM AUTHOR]

Published

2024

6. The Scintillation Counters of the High-Energy Particle Detector of the China Seismo-Electromagnetic (CSES-02) Satellite.

Author

Bartocci, Simona, Battiston, Roberto, Beolè, Stefania, Benotto, Franco, Cipollone, Piero, Coli, Silvia, Contin, Andrea, Cristoforetti, Marco, De Donato, Cinzia, De Santis, Cristian, Di Luca, Andrea, Dumitrache, Floarea, Follega, Francesco Maria, Garrafa Botta, Simone, Gebbia, Giuseppe, Iuppa, Roberto, Lega, Alessandro, Lolli, Mauro, Masciantonio, Giuseppe, and Mergè, Matteo

Subjects

*SCINTILLATION counters, *PARTICLE detectors, *PHOTOMULTIPLIERS, *COSMIC rays, *PLASTIC crystals, *SCINTILLATORS

Abstract

The High-Energy Particle Detector (HEPD-02) is one of the scientific payloads of the China Seismo-Electromagnetic Satellite (CSES-02). The HEPD-02's main purpose is to characterize the particle environment in the Earth's vicinity, identifying sudden changes in the fluxes and correlating them with solar and terrestrial phenomena. Additionally, HEPD-02 also has capabilities in detecting Gamma-Ray Bursts. At the core of HEPD-02, a tower of scintillation counters made of plastic and LYSO crystals is able to recognize electrons in the range between 3 and 100 MeV, protons and nuclei between 30 and 200 MeV/n. Plastic scintillators covering the calorimeter on five sides allow to reject particles entering from the top and not completely absorbed within its volume. In this work, the design of the HEPD-02 is reviewed in comparison to its predecessor, HEPD-01, highlighting the innovations of the new design. The design of each scintillation counter type has been fully validated through a campaign of prototype realization, testing, and characterization. The production of the scintillation counters, including the PMT selection process, is also discussed. Finally, the performance of the counters is compared with simulations, showing an agreement of within 20% with the expected performance, thereby meeting expectations. [ABSTRACT FROM AUTHOR]

Published

2024

7. Full-Scale Readout Electronics for the ECHo Experiment.

Author

Muscheid, Timo, Gartmann, Robert, Karcher, Nick, Schuderer, Felix, Neidig, Martin, Balzer, Matthias, Ardila-Perez, Luis E., Kempf, Sebastian, and Sander, Oliver

Subjects

*MICROWAVE detectors, *PARTICLE detectors, *FREQUENCY combs, *NEUTRINO mass, *SOFTWARE radio, *PIXELS

Abstract

Recent advances in the development of cryogenic particle detectors such as magnetic microcalorimeters allow the fabrication of sensor arrays with an increasing number of pixels. Since these detectors must be operated at the lowest temperatures, the readout of large detector arrays is still quite challenging. This is especially true for the ECHo experiment, which presently aims to simultaneously run 6,000 two pixel detectors to investigate the electron neutrino mass. For this reason, we developed a readout system based on a microwave SQUID multiplexer (μ MUX) that is operated by a custom software-defined radio (SDR) at room-temperature. The SDR readout electronics consist of three distinct hardware units: a data processing board with a Xilinx ZynqUS+ MPSoC; a converter board that features DACs, ADCs, and a coherent clock distribution network; and a radio frequency front-end board to translate the signals between the baseband and the microwave domains. Here, we describe the characteristics of the full-scale SDR system. First, the generated frequency comb for driving the μ MUX was evaluated. Subsequently, by operating the SDR in direct loopback, the crosstalk of the individual channels after frequency demultiplexing was investigated. Finally, the system was used with a 16-channel μ MUX to evaluate the linearity of the SDR, and the noise contributed to the overall readout setup. [ABSTRACT FROM AUTHOR]

Published

2024

8. Design and evaluation of a calibration system for portable motor vehicle emission particle number detectors.

Author

Ji, Zhe, Guo, Chengxiang, Yu, Tongzhu, Yang, Yixin, Guo, Haotian, Gui, Huaqiao, Su, Sheng, Wang, Jiguang, Ding, Yan, and Liu, Jianguo

Subjects

*PARTICLE detectors, *MOTOR vehicles, *SOOT, *CALIBRATION, *ATOMIZERS

Abstract

The supervision of the number concentration of particles emitted from motor vehicles is becoming increasingly strict. The regular calibration of portable particle number (PN) detectors is a prerequisite to ensure the effective supervision of PN. At present, the calibration of PN detectors is mostly completed in the laboratory. However, due to the complexity and poor portability of the laboratory calibration system, it is difficult to use this system for the on-site calibration of PN detectors. To this end, a portable motor vehicle emission PN detector calibration system based on the principles of negative pressure siphon atomization, differential electrical mobility classifier, and fA-level weak current measurement was developed, which could quickly and accurately calibrate the PN detector on-site. The system consists of three parts: an atomizer generator, a plate differential mobility analyzer (PDMA), and an aerosol electrometer. The atomizer generator produces NaCl particles with a median particle size of 70 nm and fluctuation of <10%. The particle size classification deviation of the PDMA is <3.7% and the counting error of the aerosol electrometer is <10%. The On-board Emissions Measurement System was calibrated as a PN detector on a self-developed portable calibration system as well as on a laboratory calibration system. The comparison results showed that the measurement results of the portable calibration system were closer to the instrument factory report certificate results, and the maximum error did not exceed 6.72%. [ABSTRACT FROM AUTHOR]

Published

2024

9. Extensive air showers and atmospheric electric fields. Synergy of space and atmospheric particle accelerators.

Author

Chilingarian, A.

Subjects

*COSMIC ray showers, *PARTICLE detectors, *SURFACE of the earth, *PARTICLES (Nuclear physics), *PARTICLE accelerators, *COSMIC rays, *ATMOSPHERIC electricity

Abstract

Various particle accelerators operate in the space plasmas, filling the Galaxy with high-energy particles (primary cosmic rays). Reaching the Earth's atmosphere, these particles originate extensive air showers (EASs) consisting of millions of elementary particles (secondary cosmic rays), covering several km2 on the ground. During thunderstorms, strong electric fields modulate the energy spectra of EAS secondary particles, changing the shower size (number of EAS electrons) and altering the primary particle's estimated energy and frequency of the surface array triggers. Impulse amplifications of particle fluxes (the so-called thunderstorm ground enhancements, TGEs) manifest themselves as large peaks in the time series of count rates of particle detectors located on the Earth's surface. Free electrons are abundant at any altitude in the atmosphere, from small to large EASs. These electrons serve as seeds for electron accelerators, which operate in the thunderous atmosphere and send particle avalanches in the direction of Earth's surface and into space (terrestrial gamma flashes, TGFs). EAS cores randomly hitting arrays of particle detectors also generate short bursts of relativistic particles. For years, particle detectors, electric field sensors, and lightning locators have gathered information about the complex interactions of secondary particle fluxes, electric fields, and lightning flashes. This information is crucial for establishing a field of high-energy physics in the atmosphere. Correlated measurements of particle fluxes modulated by strong atmospheric electric fields, registration of broadband radio and optical emission from atmospheric discharges, and registration of electric fields and various meteorological parameters lead to a better understanding of the complex processes of particle-field interactions in the terrestrial atmosphere. The cooperation of cosmic rays and atmospheric physics has led to the development of models of the origin of particle bursts recorded on the Earth's surface, vertical and horizontal profiles of electric fields, initiation of lightning flashes, etc. Interdisciplinary atmospheric science primarily requires monitoring particle fluxes around the clock by synchronized networks of identical sensors that record and store multidimensional data in databases with open, fast, and reliable access. The advances in multidimensional measurements over the past decade significantly intensified the development of new integrated models of atmospheric electricity and electron acceleration, giving more insight into understanding the modulation effects posed on EAS particles in the strong atmospheric electric fields. [ABSTRACT FROM AUTHOR]

Published

2024

10. Multispacecraft Observations of Protons and Helium Nuclei in Some Solar Energetic Particle Events toward the Maximum of Cycle 25.

Author

Bartocci, S., Battiston, R., Benella, S., Beolè, S., Burger, W. J., Cipollone, P., Contin, A., Cristoforetti, M., De Donato, C., De Santis, C., Di Luca, A., Follega, F. M., Gebbia, G., Iuppa, R., Laurenza, M., Lega, A., Lolli, M., Martucci, M., Masciantonio, G., and Mergè, M.

Subjects

*SOLAR energetic particles, *SPACE environment, *PARTICLE physics, *SUN, *PARTICLE detectors

Abstract

The intricate behavior of particle acceleration and transport mechanisms complicates the overall efforts in formulating a comprehensive understanding of solar energetic particle (SEP) events; these efforts include observations of low-energy particles (from tens of keV to hundreds of MeV) by space-borne instruments and measurements by the ground-based neutron monitors of the secondary particles generated in the Earth atmosphere by SEPs in the GeV range. Numerous space-borne missions provided good data on the nature/characteristics of these solar particles in past solar cycles, but more recently—concurrently with the rise toward the maximum of solar cycle 25—the High-Energy Particle Detector (HEPD-01) proved to be well suited for the study of solar physics and space weather. Its nominal 30–300 MeV energy range for protons can enlarge the detection capabilities of solar particles at low Earth orbit, closer to the injection limit of many SEP events. In this work, we characterize three SEP events within the first six months of 2022 through spectral and velocity dispersion analysis, assessing the response of HEPD-01 to >M1 events. [ABSTRACT FROM AUTHOR]

Published

2024

11. Determination of the response for the National Ignition Facility particle time of flight (PTOF) detector using single particle counting.

Author

Lawrence, Y., Reichelt, B. L., Wink, C. W., Rigon, G., Johnson, M. Gatu, Li, C. K., and Frenje, J. A.

Subjects

*PARTICLE detectors, *CHEMICAL vapor deposition, *IMPULSE response, *CHEMICAL detectors, *ELECTRON accelerators

Abstract

The Particle Time of Flight (PTOF) detector is a chemical vapor deposition diamond-based detector used to measure bang times in low-yield (≲ 1015 neutrons) experiments at the National Ignition Facility (NIF) at Lawrence Livermore National Laboratory (LLNL). Historically, the impulse response for PTOF diamond detectors has been obtained from x-ray timing shots on the NIF and shots on the MegaRay pulsed electron accelerator at LLNL. The impulse response may alternatively be obtained using single particle interactions with the detector, at substantially less cost and higher frequency compared to NIF timing shots, which typically occur months apart. Here, the response of a PTOF detector setup is characterized by statistically averaging a large number of single particle waveforms. A high fidelity instrument response function can be constructed in this way. This is confirmed by comparison of the single particle counting-constructed response to the impulse response function measured for the same detector at LLNL's MegaRay facility. [ABSTRACT FROM AUTHOR]

Published

2024

12. A compact matchbox-sized dust detector for lunar surface applications.

Author

Wang, Yongjun, Xu, Hengtong, Chang, Siyuan, Wen, Tiancheng, Zhuang, Jianhong, Zhang, Haiyan, Zhang, Xiaoqing, Liu, Yumei, Lu, Ziyang, Sun, Binwen, Zhang, Peisong, Zhao, Chengxuan, Ye, Xiaoyan, Liu, Min, Wang, Yi, and Li, Detian

Subjects

*LUNAR soil, *LUNAR surface, *SHORT-circuit currents, *DUST, *PARTICLE detectors, *SILICON solar cells

Abstract

In this work, a matchbox-sized dust detector with a wide measurement range was developed for the lunar surface applications. The characteristics of the detector response to lunar dust simulant deposition mass, particle size, light incidence angle, and temperature are investigated experimentally. It is found that in current study the short-circuit current of the dust detector decreases with the increase in dust deposition mass overall. However, the pattern of current reduction is closely dependent on the size of the dust particles. Specifically, for the dust particle in the range of 75–100 μm, the short-circuit current of the detector tends to decrease slowly and approximately linearly as the dust deposition mass increases, irrespective of light incidence angle. However, for the particle in the size range of 0–25 μm, the decrease of short-circuit current with dust deposition mass can be well described by an exponential function. In addition, the occlusion coefficients for different particle size distributions at different light incidence angles, ranging from −0.88 to −0.08, are also obtained, which is important for determining the mass range of dust deposited on lunar surface-mounted detector at the corresponding conditions. The present research can provide guidance for lunar dust detection with solar cell-based detector. • A lunar dust detector based on mono-crystalline silicon solar cell was developed. • The effect of lunar dust stimulant deposition on the detector was investigated. • The occlusion coefficient under different conditions was determined. [ABSTRACT FROM AUTHOR]

Published

2024

13. The Global Characteristics of Electrons Near the Inner Edge of the Inner Radiation Belt.

Author

Walton, S. D., Lejosne, S., and Claudepierre, S. G.

Subjects

PARTICLE detectors, RADIATION belts, DYNAMIC pressure, WIND speed, ELECTRON traps, SOLAR wind

Abstract

Energetic electrons around the inner edge of the inner radiation belt (L≲ $\lesssim $1.3) have not been studied to the extent of the rest of the inner belt and certainly not to that of the outer radiation belt. Yet, the behavior of electrons at the inner edge of the inner belt could improve our understanding of important dynamics deep within Earth's magnetosphere. Previous work has analyzed these electrons during either isolated events or via significantly limited statistical studies, and it remains unclear what the particular drivers of electron flux enhancements in this region may be. Here, we present a broad statistical study of electrons around the inner edge of the inner radiation belt, utilizing the 7‐year data set of the MagEIS particle detectors aboard both Van Allen Probes spacecraft. Moreover, we separate electron flux measurements into stably trapped and quasi‐trapped electrons and directly compare their behavior. We find both populations to be variable in L and energy, as well as showing a clear magnetic local time (MLT) asymmetry. Potential drivers are also explored, where we demonstrate an association between increased electron fluxes in this region and heightened solar wind speed, Sym‐H, dynamic pressure, southward IMF Bz ${\mathrm{B}}_{z}$ and most prominently with the AU and AL indices. Key Points: The global behavior of electrons near the inner edge of the inner radiation belt are statistically analyzedStably and quasi‐trapped electrons are dependent on L and MLT, and are particularly responsive to AU, AL, VSW ${\mathrm{V}}_{SW}$ and Sym‐H≳ $\gtrsim $70 keV quasi‐trapped electron fluxes appear most variable and sensitive to geomagnetic activity [ABSTRACT FROM AUTHOR]

Published

2024

14. TOP detector for particle identification at Belle II.

Author

Torassa, Ezio

Subjects

*PARTICLE detectors, *CHERENKOV counters, *DETECTORS, *HADRONS, *ACQUISITION of data

Abstract

The Time-Of-Propagation (TOP) counter is a ring-imaging Cherenkov detector designed to identify the charged hadrons in the barrel region of the Belle II detector. The Belle II experiment collected data delivered by the SuperKEKB accelerator from March 2019 to June 2022. After the first run period (Run1), a long shutdown (LS1) was dedicated to implement several accelerator and detector upgrades. The second collision period (Run2) was started in January 2024. The components of the TOP detector and the performance during the Run1 will be reported and the detector upgrade during LS1 and future upgrades will be described. [ABSTRACT FROM AUTHOR]

Published

2024

15. Novel Liquid Argon Time-Projection Chamber Readouts.

Author

Asaadi, Jonathan, Dwyer, Daniel A., and Russell, Brooke

Abstract

Liquid argon time-projection chambers (LArTPCs) have become a prominent tool for experiments in particle physics. Recent years have yielded significant advances in the techniques used to capture the signals generated by these cryogenic detectors. This article summarizes these novel developments for detection of ionization electrons and scintillation photons in LArTPCs. New methods to capture ionization signals address the challenges of scaling traditional techniques to the large scales necessary for future experiments. Pixelated readouts improve signal fidelity and expand the applicability of LArTPCs to higher-rate environments. Methods that leverage amplification in argon enable measurements in the keV regime and below. Techniques to enhance collection of argon scintillation photons improve calorimetry and expand the physics program for very large detectors. Future efforts aim to demonstrate systems for the combined detection of both electrons and photons. [ABSTRACT FROM AUTHOR]

Published

2024

16. Exploring charge transport dynamics in a cryogenic P-type germanium detector.

Author

Acharya, P, Fritts, M, Mei, D-M, Wang, G-J, Mahapatra, R, and Platt, M

Subjects

*IMPACT ionization, *ENERGY levels (Quantum mechanics), *PARTICLE detectors, *BINDING energy, *GERMANIUM detectors, *DARK matter

Abstract

This study explores the dynamics of charge transport within a cryogenic P-type Ge particle detector, fabricated from a crystal cultivated at the University of South Dakota. By subjecting the detector to cryogenic temperatures and an Am-241 source, we observe evolving charge dynamics and the emergence of cluster dipole states, leading to the impact ionization process at 40 mK. Our analysis focuses on crucial parameters: the zero-field cross-section of cluster dipole states and the binding energy of these states. For the Ge detector in our investigation, the zero-field cross-section of cluster dipole states is determined to be 8.45 × 10−11 ± 4.22 × 10−12 cm2. Examination of the binding energy associated with cluster dipole states, formed by charge trapping onto dipole states during the freeze-out process, reveals a value of 0.034 ± 0.0017 meV. These findings shed light on the intricate charge states influenced by the interplay of temperature and electric field, with potential implications for the sensitivity in detecting low-mass dark matter. [ABSTRACT FROM AUTHOR]

Published

2024

17. Energy flow in light scattering by a small conducting sphere.

Author

Arnoldus, Henk F.

Subjects

*LIGHT scattering, *ELECTRIC dipole moments, *MAGNETIC dipole moments, *PARTICLE detectors, *POYNTING theorem

Abstract

Radiation energy scattered by a small particle can be expected to travel from the particle to a detector in the far field along the field lines of the Poynting vector. We consider the scattering off a small conducting sphere, for which only the induced electric and magnetic dipole moments contribute to the emitted radiation. Field lines of the energy flow due to interference between fields radiated by the electric and magnetic dipoles appear to form closed loops in the vicinity of the particle. Energy flows out of the particle at one side and then returns to the particle at the other side, and as such, this energy flow does not contribute to the radiated power. At larger distances, energy flows away from the particle at one side of the particle, but on the other side, radiation flows from infinity toward the particle. The energy for the scattered radiation is provided by the incident field. The energy flow is due to interference between the incident field and the scattered radiation, known as extinction. The flow pattern of this energy exhibits numerous singularities and vortices, and closed-loop flows near the particle. In the far field, energy flows along counter-oriented field line bundles, with only the net power flowing inward. [ABSTRACT FROM AUTHOR]

Published

2023

18. Particle tracking, recognition and LET evaluation of out-of-field proton therapy delivered to a phantom with implants.

Author

Bălan, Cristina, Granja, Carlos, Mytsin, Gennady, Shvidky, Sergey, Molokanov, Alexander, Marek, Lukas, Chiș, Vasile, and Oancea, Cristina

Subjects

*LINEAR energy transfer, *PARTICLE detectors, *SEMICONDUCTOR detectors, *PROTON scattering, *FAST neutrons, *PROTON beams

Abstract

Objective. This study aims to assess the composition of scattered particles generated in proton therapy for tumors situated proximal to some titanium (Ti) dental implants. The investigation involves decomposing the mixed field and recording Linear Energy Transfer (LET) spectra to quantify the influence of metallic dental inserts located behind the tumor. Approach. A therapeutic conformal proton beam was used to deliver the treatment plan to an anthropomorphic head phantom with two types of implants inserted in the target volume (made of Ti and plastic, respectively). The scattered radiation resulted during the irradiation was detected by a hybrid semiconductor pixel detector MiniPIX Timepix3 that was placed distal to the Spread-out Bragg peak. Visualization and field decomposition of stray radiation were generated using algorithms trained in particle recognition based on artificial intelligence neural networks (AI NN). Spectral sensitive aspects of the scattered radiation were collected using two angular positions of the detector relative to the beam direction: 0° and 60°. Results. Using AI NN, 3 classes of particles were identified: protons, electrons & photons, and ions & fast neutrons. Placing a Ti implant in the beam's path resulted in predominantly electrons and photons, contributing 52.2% of the total number of detected particles, whereas for plastic implants, the contribution was 65.4%. Scattered protons comprised 45.5% and 31.9% with and without metal inserts, respectively. The LET spectra were derived for each group of particles identified, with values ranging from 0.01 to 7.5 keV μ m−1 for Ti implants/plastic implants. The low-LET component was primarily composed of electrons and photons, while the high-LET component corresponded to protons and ions. Significance. This method, complemented by directional maps, holds the potential for evaluating and validating treatment plans involving stray radiation near organs at risk, offering precise discrimination of the mixed field, and enhancing in this way the LET calculation. [ABSTRACT FROM AUTHOR]

Published

2024

19. The Unruh–DeWitt model and its joint interacting Hilbert space.

Author

Tjoa, Erickson and Gray, Finnian

Subjects

*QUANTUM field theory, *FOCK spaces, *TENSOR products, *PARTICLE detectors, *CURVED spacetime, *HILBERT space, *SCALAR field theory

Abstract

In this work we make the connection between the Unruh–DeWitt (UDW) particle detector model applied to quantum field theory in curved spacetimes and the rigorous construction of the spin-boson (SB) model. With some modifications, we show that existing results about the existence of a SB ground state can be adapted to the UDW model. In the most relevant scenario involving massless scalar fields in (3+1)-dimensional globally hyperbolic spacetimes, where the UDW model describes a simplified model of light–matter interaction, we argue that common choices of the spacetime smearing functions regulate the ultraviolet behaviour of the model but can still exhibit infrared (IR) divergences. In particular, this implies the well-known expectation that the joint interacting Hilbert space of the model cannot be described by the tensor product of a two-dimensional complex Hilbert space and the Fock space of the vacuum representation. We discuss the conditions under which this problem does not arise and the relevance of the operator-algebraic approach for better understanding of particle detector models and their applications.Our work clarifies the connection between obstructions due to Haag's theorem and IR bosons in the SB models, and paves the way for more rigorous study of entanglement and communication in the UDW framework involving multiple detectors. [ABSTRACT FROM AUTHOR]

Published

2024

20. Alpha particle detection based on low leakage and high-barrier vertical PtOx/β-Ga2O3 Schottky barrier diode.

Author

Bai, Shiyu, Hou, Xiaohu, Meng, Xiangdong, Ren, Lei, Li, Chen, Han, Zhao, Yu, Shunjie, Liu, Yan, Peng, Zhixin, Han, Yuncheng, Zhao, Xiaolong, Zhou, Xuanze, Xu, Guangwei, and Long, Shibing

Subjects

*NUCLEAR counters, *ALPHA rays, *PARTICLE detectors, *SCHOTTKY barrier diodes, *PARTICLE physics

Abstract

High-performance radiation detectors are essential in many sectors spanning medical diagnostics, nuclear control, and particle physics. Ultrawide bandgap semiconductor materials have become one of the most promising candidates due to their excellent performance. Here, based on β-Ga2O3, a Schottky diode-type alpha particle detector was demonstrated. In order to reduce the reverse leakage current of the large-area device, the metal-oxide electrode PtOx was introduced to form high-barrier contacts (1.83 eV) with Ga2O3. The device exhibits a low leakage current density of 63 pA/cm2 at −100 V and apparent energy spectra of 241Am generated alpha particles with an energy of 5.486 MeV at various reverse voltages from −40 to −120 V. The charge collection efficiency (CCE) and energy resolution of the device (at −120 V) are 31.7% and 15.3%, respectively. Meanwhile, the mechanism of interaction between alpha particles and β-Ga2O3 was analyzed, and a 45° oblique incidence was adopted to increase the deposited energy of alpha particles in the depletion region. Furthermore, the differences between actual CCE and theoretical CCE are investigated as guidance for further improving detector performance. This work reveals the great potential and good prospects of Ga2O3 as an economical, efficient, and radiation-resistant ionizing radiation detector. [ABSTRACT FROM AUTHOR]

Published

2024

21. Development of fast 2.5 MeV neutron detectors for high-intensity stray magnetic field environments.

Author

Molin, A. Dal, Guiotto, F., Putignano, O., Rosa, M. Dalla, Franz, P., Grosso, G., Monguzzi, A., Cippo, E. Perelli, Pollice, L., Rigamonti, D., Tedoldi, L. G., Zuin, M., and Tardocchi, M.

Subjects

*NEUTRON counters, *PARTICLE detectors, *NEUTRON measurement, *MAGNETIC confinement, *MAGNETIC fields, *SCINTILLATORS

Abstract

Several small to medium-scale magnetic confinement fusion devices operate using deuterium as fuel. These low neutron rate (108–1010 n/s) devices rely on 2.45 MeV neutron measurements to validate physical models and to assess their performance. Given the modest rate, neutron monitors have to be placed as close as possible to the machine to maximize data gathering. In these regions, intense stray magnetic fields could affect the detector's performance. In this work, the development of a neutron detector based on an EJ-276D scintillator crystal coupled with a SiPM and a custom-made readout system is presented. The detector has particle discrimination capability and is insensitive to magnetic fields. [ABSTRACT FROM AUTHOR]

Published

2024

22. Module Tester for Positron Emission Tomography and Particle Physics.

Author

Baranyai, David, Oniga, Stefan, Gyongyosi, Balazs, Ujvari, Balazs, and Mohamed, Attia

Subjects

POSITRON emission tomography, PARTICLE detectors, PARTICLE physics, MONTE Carlo method, ANALOG-to-digital converters

Abstract

The combination of high-density, high-time-resolution inorganic scintillation crystals such as Lutetium Yttrium Oxyorthosilicate (LYSO), Yttrium Orthosilicate (YSO) and Bismuth Germanate (BGO) with Silicon Photomultiplier (SiPM) sensors is widely employed in medical imaging, particularly in Positron Emission Tomography (PET), as well as in modern particle physics detectors for precisely timing sub-detectors and calorimeters. During the assembly of each module, following individual component testing, the crystals and SiPMs are bonded together using optical glue and enclosed in a light-tight, temperature-controlled cooling box. After integration with the readout electronics, the bonding is initially tested. The final readout electronics typically comprise Application-Specific Integrated Circuits (ASICs) or low-power Analog-to-Digital Converters (ADCs) and amplifiers, designed not to heat up the temperature-sensitive SiPM sensors. However, these setups are not optimal for testing the optical bonding. Specific setups were developed to test the LYSO + SiPM modules that are already bonded but not enclosed in a box. Through large data collection, small deviations in bonding can be detected if the SiPMs and LYSOs have been thoroughly tested before our measurement. The Monte Carlo simulations we used to study how parameters—which are difficult to measure in the laboratory (LYSO absorption length, refractive index of the coating)—affect the final result. Our setups for particle physics and PET applications are already in use by research institutes and industrial partners. [ABSTRACT FROM AUTHOR]

Published

2024

23. High energy resolution CsPbBr3 alpha particle detector with a full-customized readout application specific integrated circuit.

Author

Zhang, Xin, Bai, Ruichen, Fu, Yuhao, Hao, Yingying, Peng, Xinkai, Wang, Jia, Ge, Bangzhi, Liu, Jianxi, Hu, Yongcai, Ouyang, Xiaoping, Jie, Wanqi, and Xu, Yadong

Subjects

APPLICATION-specific integrated circuits, ALPHA rays, ELECTRONIC noise, PARTICLE detectors, ELECTRONIC systems, SIGNAL processing, SPECTRAL imaging

Abstract

α particles must be monitored to be managed as radioactive diagnostic agents or nuclear activity indicators. The new generation of perovskite detectors suffer from limited energy resolution, which affects spectroscopy and imaging applications. Here, we report that the solution-grown CsPbBr3 crystal exhibits a low and stable dark current (34.6 nA·cm−2 at 200 V) by thinning the as-grown crystal to decrease the high concentration CsPb2Br5 phase near the surface. The introduction of the Schottky electrode for the CsPbBr3 detector further reduces the dark current and improves the high-temperature stability. An energy resolution of 6.9% is achieved with the commercial electronic system, while the effects of air scattering and absorption are investigated. Moreover, 1.1% energy resolution is recognized by a full-customized readout application-specific integrated circuit without any additional signal processing, which matches well with the given parameters of the CsPbBr3 detector by reducing the parasitic capacitance and electronic noise. By developing a synergistic strategy of thinning the perovskite crystal, employing Schottky electrode and full-customised readout application specific integrated circuit to supress dark current and electronic noise, the authors report an energy resolution of 1.1% for perovskite α-particle detector. [ABSTRACT FROM AUTHOR]

Published

2024

24. Energetic Charged Particle Measurements During Juno's Two Close Io Flybys.

Author

Paranicas, C., Mauk, B. H., Clark, G., Kollmann, P., Nénon, Q., Ebert, R. W., Szalay, J. R., Sulaiman, A. H., Connerney, J. E. P., and Bolton, S.

Subjects

*ATMOSPHERE of Jupiter, *LUNAR surface, *PARTICLE detectors, *JUNO (Space probe), *PROTON beams, *ELECTRON beams, *ELECTRON energy loss spectroscopy

Abstract

On days 2023‐364 and 2024‐034, the Juno spacecraft made close passages of Jupiter's moon Io, at altitudes of about 1,500 km. Data obtained from the first flyby, when the spacecraft was on magnetic field lines connected to both Jupiter and Io, revealed deep flux decreases. In addition, Juno's energetic particle detectors observed tens to hundreds of keV electron and proton beams. Such beams could be generated near Jupiter on field lines associated with Io. The second encounter occurred in the plasma wake and a more modest flux decrease was observed. Furthermore, data from both encounters suggest a spatially extensive decrease in >1 MeV electrons that includes regions inward of Io's orbit. In the immediate vicinity of Io, signatures of absorption likely dominate the data whereas diffusion and wave‐particle interactions are expected to be needed to understand MeV electron data in the wider spatial region around Io. Plain Language Summary: Jupiter's magnetospheric plasma overtakes Io in its orbit. This causes a cavity to be formed over the hemisphere of Io that leads its orbital motion. Within this cavity subtle details of the plasma and energetic charged particle environment can be extracted from the signal, usually dominated by radiation at these distances. Examples include beams traveling in the direction from Jupiter to the moon, with little evidence of reflection at Io. Another major finding of this work is that there is a large region both along Io's orbit and even radially inward of it with a lower level of MeV electron flux. Guided by previous modeling, the most likely candidates for shaping the data are absorption by the moon, wave‐particle interactions that can scatter particles into Jupiter's atmosphere, and diffusion. Key Points: Deep flux decreases over Io and in its immediate wake caused by losses to the moon's surface were observed in Juno JEDI dataJuno JEDI detected narrow field‐aligned beams of electrons and protons directed toward Io's north poleMoon absorption and wave‐particle interactions may explain the loss of >1 MeV electrons that extend both inward and outward of Io's orbit [ABSTRACT FROM AUTHOR]

Published

2024

25. A method of reconstruction of anisotropic fluxes of geomagnetically trapped particles from in-flight measurements of high precision.

Author

Leonov, A.A., Malakhov, V.V., Mayorov, A.G., Mikhailov, V.V., and Alekseev, V.V.

Subjects

*VECTOR fields, *PARTICLE detectors, *GEOMAGNETISM, *MONTE Carlo method, *SPACE vehicles

Abstract

High anisotropy of geomagnetically trapped particles' fluxes requires utilization of a complex methodology for their reconstruction from in-flight measurements. For precise position-sensitive instruments operating in the event-by-event mode, a standard approach is the one originally developed for the SAMPEX/MAST experiment. It consists in calculation of the instrument's effective areas averaged over gyro-phase angle as a function of pitch angle of detected particles for detector's different orientations relative to the geomagnetic field vector. This orientation normally changes as the instrument moves in space. Moreover, some space vehicles bearing a measuring instrument may and do change their orientation during flight by rotation of the instrument or as a whole. Each possible orientation needs an independent calculation of effective areas for each possible pitch angle, which is usually done by means of Monte-Carlo simulation. Therefore, especially for sophisticated devices, the calculation of an accurate and representative response function (consisting of a set of effective areas) may involve a vast amount of computation. In this paper, we propose a simplified approach, which is based on the assumption that for an anisotropic flux, the angular sphere the particles come to the detector from can be split into solid angle domains, within which the flux can be treated as isotropic. This allows one to use much easier computed geometrical factor or acceptance of the instrument as the proportionality factor. This method suggests that it can be calculated with respect to registration of the particles from these domains (we call it partial acceptance). The main advantage of the presented method is that the whole set of partial acceptances for each instrument orientation relative to the geomagnetic field vector and for all available values of (equatorial) pitch-angle for this orientation can be obtained from one simulation sample (for the given energy) of isotropic flux. [ABSTRACT FROM AUTHOR]

Published

2024

26. The European Participation to the Electron Ion Collider.

Author

Antonioli, Pietro

Subjects

*PARTICLE range (Nuclear physics), *PARTICLE detectors, *PARTICLES (Nuclear physics), *NUCLEAR physics, *PARTICLE physics, *ELECTRON beams, *MUONS

Abstract

This article provides an overview of the European participation in the construction of the Electron Ion Collider (EIC), a significant project in nuclear physics. The EIC aims to study the structure of nucleons and nuclei by colliding highly polarized electrons with high-energy beams. The European community is actively involved in the project, with recommendations from the Nuclear Physics European Collaboration Committee (NuPECC) emphasizing European participation. European institutions are also contributing to the design and construction of the ePIC detector for the EIC experiment. The article emphasizes the importance of the EIC in advancing our understanding of the fundamental building blocks of matter and highlights the collaborative efforts of scientists from around the world. The European nuclear science community sees the EIC as an opportunity for further advancements in this field. [Extracted from the article]

Published

2024

27. Design Considerations for the Optimization of λ-SQUIDs.

Author

Schuster, Constantin and Kempf, Sebastian

Subjects

*PENETRATION depth (Superconductors), *HEAT capacity, *QUANTUM efficiency, *TRANSITION temperature, *PARTICLE detectors, *CALORIMETERS

Abstract

Cryogenic microcalorimeters are key tools for high-resolution X-ray spectroscopy due to their excellent energy resolution and quantum efficiency close to 100%. Multiple types of microcalorimeters exist, some of which have already proven outstanding performance. Nevertheless, they cannot yet compete with cutting-edge grating or crystal spectrometers. For this reason, novel microcalorimeter concepts are continuously developed. One such concept is based on the strong temperature dependence of the magnetic penetration depth of a superconductor operated close to its transition temperature. This so-called λ -SQUID provides an in-situ tunable gain and promises to reach sub-eV energy resolution. Here, we present some design considerations with respect to the optimization of such a detector that are derived by analytic means. We particularly show that for this detector concept the heat capacity of the sensor should match the heat capacity of the absorber. [ABSTRACT FROM AUTHOR]

Published

2024

28. Energetic Proton Losses Reveal Io's Extended and Longitudinally Asymmetrical Atmosphere.

Author

Huybrighs, H. L. F., van Buchem, C. P. A., Blöcker, A., Dols, V., Bowers, C. F., and Jackman, C. M.

Subjects

CHARGE exchange, PARTICLE detectors, PROTONS, MAGNETIC field effects, PLASMA flow, ATMOSPHERIC nucleation

Abstract

Along the I24, I27, and I31 flybys of Io (1999–2001), the Energetic Particle Detector (EPD) onboard the Galileo spacecraft observed localized regions of energetic protons losses (155–1,250 keV). Using back‐tracking particle simulations combined with a prescribed atmospheric distribution and a magnetohydrodynamics (MHD) model of the plasma/atmosphere interaction, we investigate the possible causes of these depletions. We focus on a limited region within two Io radii, which is dominated by Io's SO2 atmosphere. Our results show that charge exchange of protons with the SO2 atmosphere, absorption by the surface and the configuration of the electromagnetic field contribute to the observed proton depletion along the Galileo flybys. In the 155–240 keV energy range, charge exchange is either a major or the dominant loss process, depending on the flyby altitude. In the 540–1,250 keV range, as the charge exchange cross sections are small, the observed decrease of the proton flux is attributed to absorption by the surface and the perturbed electromagnetic fields, which divert the protons away from the detector. From a comparison between the modeled losses and the data we find indications of an extended atmosphere on the day/downstream side of Io, a lack of atmospheric collapse on the night/upstream side as well as a more global extended atmospheric component (>1 Io radius). Our results demonstrate that observations and modeling of proton depletion around the moon constitute an important tool to constrain the electromagnetic field configuration around Io and the radial and longitudinal atmospheric distribution, which is still poorly understood. Plain Language Summary: Io is a moon of Jupiter with active volcanoes and an atmosphere of which the structure and variability is poorly understood. A fascinating object on its own, neutral gas from Io also serves as the main source of plasma in Jupiter's magnetosphere. Improving our understanding of Io's atmosphere will allow us to better understand the precise link between Io's neutral environment and the plasma torus surrounding Jupiter. In this work we analyze data from the historic Galileo spacecraft that encountered Io. Specifically, we analyze regions close to Io where (normally abundant) energetic protons are disappearing. We find that charge exchange between these particles and Io's atmosphere along with the effect of the electric and magnetic fields on the paths of these particles can cause such decreases. Charge exchange with the atmosphere is either a major or the dominant source of losses, depending on the flyby altitude. The losses of the protons are related to Io's atmosphere and hint at an atmosphere that is more extended on Io's day side (also the downstream side from the plasma flow's point of view), doesn't collapse fully on the night (upstream) side, and appears to be more extended than we assumed. Key Points: Atmospheric charge exchange is a major or dominant loss process of energetic protons (155–224 keV) during three close Galileo flybys of IoProton losses suggest an expanded atmosphere on the day/downstream side and a lack of atmospheric collapse on the night/upstream sideDiscrepancies between the data and model hint at a global large scale height atmosphere [ABSTRACT FROM AUTHOR]

Published

2024

29. Measuring Low Plasma Density in the Earth's Equatorial Magnetosphere From Magnetosonic Waves.

Author

Horne, R. B., Daggitt, T. A., Meredith, N. P., Glauert, S. A., Liu, X., and Chen, L.

Subjects

*PLASMA density, *PARTICLE detectors, *MAGNETOSPHERE, *PLASMA waves, *PLASMA oscillations, *ELECTRON density, *ORBITS of artificial satellites

Abstract

The plasma density is one of the most fundamental quantities of any plasma yet measuring it in space is exceptionally difficult when the density is low. Measurements from particle detectors are contaminated by spacecraft photoelectrons and methods using plasma wave emissions are hampered by natural plasma instabilities which dominate the wave spectrum. Here we present a new method which calculates the density from magnetosonic waves near the lower hybrid resonance frequency. The method works most effectively when the ratio of the plasma to cyclotron frequency is fpe/fce < 3.5. The method provides a lower bound on the plasma density. Using the new method we show that wave acceleration of electrons to relativistic energies is increased by orders of magnitude. The method enables years of satellite data to be re‐analyzed for the Earth and the effectiveness of wave acceleration at the Earth, Jupiter and Saturn to be re‐assessed. Plain Language Summary: The electron plasma density is a fundamental quantity of any plasma, but it is very difficult to measure in space using satellites. Satellites charge to different potentials with repel or attract electrons making the true measurement very difficult. The plasma density can be determined from wave oscillations at the plasma frequency, but the waves are difficult to identify as the wave spectrum is often dominated by other much stronger waves. Here we analyze satellite data and show that magnetosonic waves near the lower hybrid resonance frequency can be used to calculate the plasma density. This method provides a lower bound on the density. We show that this lower density leads to much faster electron acceleration by wave‐particle interactions, accelerates electrons to much higher energies and increases the electron flux at one MeV by two orders of magnitude or more. The method enables the importance of electron acceleration at the Earth, Jupiter and Saturn to be re‐evaluated. Key Points: New method to calculate plasma density from magnetosonic waves near the lower hybrid resonance frequencyMethod enables low densities to be measured near the magnetic equatorLow density increases wave acceleration of electrons by orders of magnitude [ABSTRACT FROM AUTHOR]

Published

2024

30. Cosmo ArduSiPM: An All-in-One Scintillation-Based Particle Detector for Earth and Space Application.

Author

Bocci, Valerio, Ali, Babar, Chiodi, Giacomo, Kubler, Dario, Iacoangeli, Francesco, Masi, Lorenza, and Recchia, Luigi

Subjects

*PARTICLE detectors, *SIGNAL processing, *SCINTILLATORS, *SOFTWARE architecture, *CUBESATS (Artificial satellites), *MICROCONTROLLERS, *SYSTEMS on a chip

Abstract

Thanks to advancements in silicon photomultiplier sensors (SiPMs) and system-on-chip (SoC) technology, our INFN Roma1 group developed ArduSiPM in 2012, the first all-in-one scintillator particle detector in the literature. It used a custom Arduino Due shield to process fast signals, utilizing the Microchip Sam3X8E SoC's internal peripherals to control and acquire SiPM signals. The availability of radiation-tolerant SoCs, combined with the goal of reducing system space and weight, led to the development of an innovative second-generation board, a better-performing device called Cosmo ArduSiPM, suitable for space missions. The architecture of the new detector is based on the Microchip SAMV71 300 MHz, 32-bit ARM® Cortex®-M7 (Microchip Technology Inc., Chandler, AZ, USA). While the analog front-end is essentially identical to the ArduSiPM, it utilizes components with the smallest possible package. The board fits in a CubeSat module. Thanks to the compact design, the board has two independent channels, with a total weight of only 40 grams within a CubeSat form factor. The ArduSiPM architecture is based on a single microcontroller and fast discrete analog electronics. It benefits from the continued development of SoCs related to the IoT (Internet of Things) market. Compared with a system with a custom ASIC, this architecture based on software and SoC capabilities offers considerable advantages in terms of cost and development time. The ability to incorporate new commercial SoCs, continuously emerging from advancements in the aerospace and automotive industries, provides the system with a robust foundation for sustained growth over the years. A detailed characterization of the hardware and the system's response to different photon fluxes is presented in this article. Additionally, coupling the device with a scintillator was tested at the end of this article as a preliminary trial for future measurements, showing potential for further enhancement of the detector's capabilities. [ABSTRACT FROM AUTHOR]

Published

2024

31. Ultra-high-granularity detector simulation with intra-event aware generative adversarial network and self-supervised relational reasoning.

Author

Hashemi, Baran, Hartmann, Nikolai, Sharifzadeh, Sahand, Kahn, James, and Kuhr, Thomas

Subjects

GENERATIVE adversarial networks, VERTEX detectors, PARTICLE detectors, DETECTORS

Abstract

Simulating high-resolution detector responses is a computationally intensive process that has long been challenging in Particle Physics. Despite the ability of generative models to streamline it, full ultra-high-granularity detector simulation still proves to be difficult as it contains correlated and fine-grained information. To overcome these limitations, we propose Intra-Event Aware Generative Adversarial Network (IEA-GAN). IEA-GAN presents a Transformer-based Relational Reasoning Module that approximates an event in detector simulation, generating contextualized high-resolution full detector responses with a proper relational inductive bias. IEA-GAN also introduces a Self-Supervised intra-event aware loss and Uniformity loss, significantly enhancing sample fidelity and diversity. We demonstrate IEA-GAN's application in generating sensor-dependent images for the ultra-high-granularity Pixel Vertex Detector (PXD), with more than 7.5 M information channels at the Belle II Experiment. Applications of this work span from Foundation Models for high-granularity detector simulation, such as at the HL-LHC (High Luminosity LHC), to simulation-based inference and fine-grained density estimation. Simulating responses of a full particle physics detector with high granularity is computationally very expensive. Here, the authors develop a deep generative model that is able to model a detector with millions of information channel with good performances, reducing both storage demand and CPU time. [ABSTRACT FROM AUTHOR]

Published

2024

32. Measurements of Particle Fluxes, Electric Fields, and Lightning Occurrences at the Aragats Space-Environmental Center (ASEC).

Author

Chilingarian, A., Karapetyan, T., Sargsyan, B., Khanikyanc, Y., and Chilingaryan, S.

Subjects

ELECTRIC fields, PARTICLE acceleration, LIGHTNING, ATMOSPHERIC boundary layer, ATMOSPHERIC layers, CUMULONIMBUS, COSMIC rays, SLOPE stability

Abstract

To catalyze transformative advancements in High-energy Physics in the Atmosphere (HEPA), a comprehensive understanding of particle fluxes, electric fields, and lightning occurrences across atmospheric layers is imperative. This paper elucidates the instrumentation and capabilities of the Aragats Space-Environmental Center (ASEC), which encompasses measurement tools for various cosmic ray species, near-surface electric fields, and lightning events integrated across high-mountain research station at slopes of Mt. Aragats and the highest mountains of Eastern Europe and Germany. Through these measurements, we aim to elucidate models of particle acceleration mechanisms and the charge distribution within the lower atmosphere. We introduce an Advanced Data Extraction Infrastructure (ADEI) integrated with sophisticated statistical analysis tools to facilitate rapid access to this wealth of data. Despite the significance of these atmospheric processes, the intricate interplay between thundercloud electrification, lightning activity, wideband radio emissions, and particle fluxes remains poorly understood. A particularly compelling avenue of inquiry lies in exploring the relationship between high-energy atmospheric phenomena, intracloud electric fields, and lightning initiation. Furthermore, investigations into accelerated structures within geospace plasmas hold promise for shedding light on particle acceleration processes, potentially extending to higher energies within analogous structures in cosmic plasmas. This paper also examines practical methodologies for extracting meaningful physical insights from temporal datasets, such as correlating surges in particle flux intensity with variations in near-surface electric field strength and precipitation patterns. Additionally, we explore the utility of wideband field and interferometer antenna signals in this context, offering valuable avenues for further research and analysis. Through these endeavors, we aim to deepen our understanding of high-energy atmospheric processes and their broader implications for terrestrial and cosmic phenomena. [ABSTRACT FROM AUTHOR]

Published

2024

33. Cold Electron Temperature in the Inner Magnetosphere Estimated Through the Dispersion Relation of ECH Waves From the Arase Satellite Observations.

Author

Taki, Tomoe, Kurita, Satoshi, Kojima, Hirotsugu, Kasahara, Yoshiya, Matsuda, Shoya, Matsuoka, Ayako, Kazama, Yoichi, Jun, Chae‐Woo, Wang, Shiang‐Yu, Tam, Sunny W. Y., Chang, Tzu‐Fang, Wang, Bo‐Jhou, Miyoshi, Yoshizumi, and Shinohara, Iku

Subjects

DISPERSION relations, COLD (Temperature), ELECTRON temperature, PARTICLE detectors, MAGNETOSPHERE, ELECTRON density, ORBITS of artificial satellites

Abstract

We have analyzed Electrostatic Electron Cyclotron Harmonic (ECH) waves observed using interferometry observation mode performed by the Arase satellite to estimate low‐energy electron temperatures. Interferometry can be used to calculate velocities, but the Arase satellite can only perform interferometry observations in a one‐dimensional direction. We proposed a method to estimate the wave vector of the observed ECH waves from the observed electric fields and calculated the phase velocity for each frequency. We determined the particle parameters from the particle detector and the upper hybrid resonance and estimated the unknown low‐energy electron temperature from the agreement between the observed ECH dispersion relation and the theoretical dispersion curves. We performed our analysis for six events and found that the low‐energy electron temperature in the observed region is on the order of 1 eV. Plain Language Summary: Low‐energy electrons, which are dominant in the Earth's inner magnetosphere, are difficult to observe directly with particle instruments due to satellite charging. We have successfully estimated the plasma environment by deriving the frequency‐wavenumber relations of Electrostatic Electron Cyclotron Harmonic (ECH) waves in the inner magnetosphere and comparing them with the theoretical relations. To derive the frequency‐wavenumber relationship of the ECH waves, it is necessary to obtain the phase velocity of the ECH waves by satellite observations. We proposed a method to determine the unobserved components of the ECH wave using interferometry observations by the Arase satellite and calculated the phase velocity using this method. Thus, the obtained low‐energy electron temperatures were all 1 eV, indicating that there are many low‐energy electrons of the order of 1 eV in the inner magnetosphere. Key Points: Phase velocities of electron cyclotron harmonic (ECH) waves were calculated using interferometry observations from the Arase satelliteThe low‐energy electron temperature was estimated based on the dispersion relation of the ECH waveIt is found that low‐energy electrons of the order of 1 eV account for the majority of the electron density distribution [ABSTRACT FROM AUTHOR]

Published

2024

34. Novel fully-heterogeneous GNN designs for track reconstruction at the HL-LHC.

Author

Caillou, Sylvain, Collard, Christophe, Rougier, Charline, Stark, Jan, Torres, Heberth, and Vallier, Alexis

Subjects

*LARGE Hadron Collider, *PARTICLE detectors, *DATA structures, *MACHINE learning

Abstract

Data from the LHC detectors are not easily represented using regular data structures. These detectors are comprised of several species of subdetectors and therefore produce heterogeneous data. LHC detectors are highly granular by design so that nearby particles may be distinguished. As a consequence, LHC data are sparse, in that many detector channels are not active during a given collision event. Graphs offer a flexible and efficient alternative to rectilinear data structures for representing LHC data. Accordingly, graph-based machine learning algorithms are becoming increasingly popular for a large number of LHC physics tasks [1, 2]. This popularity, and the corresponding potential for substantial increase in physics output, are illustrated on the cover of a recent issue [3] of the CERN Courier magazine. The graphs used in almost all practical applications at the LHC so far are homogeneous, i.e. each node is assigned the same features, and each edge is assigned the same features. In other words, the power of graphs to represent sparse data has been exploited in applications for the LHC, but the potential of graphs to represent heterogeneous data has not. The pink graph on the cover of the CERN Courier [3] can be seen as an illustration of this limitation: all nodes are pink, regardless of their position in the detector. We present novel fully-heterogeneous GNN designs and apply them to simulated data from a tracking detector that resembles the trackers that will be used at the HL-LHC. It contains a pixel subsystem that provides 3D hits and a strip subsystem that provides 2D hits. We present a new design which solves the degraded performance observed in the strip detector in the first GNNbased tracking studies presented by the ATLAS Collaboration [4]. [ABSTRACT FROM AUTHOR]

Published

2024

35. Simulation of Hadronic Interactions with Deep Generative Models.

Author

Pham, Tuan Minh and Ju, Xiangyang

Subjects

*LARGE Hadron Collider, *PARTICLE detectors, *HADRON interactions, *COMPUTER simulation, *PHENOMENOLOGICAL theory (Physics)

Abstract

Accurate simulation of detector responses to hadrons is paramount for all physics programs at the Large Hadron Collider (LHC). Central to this simulation is the modeling of hadronic interactions. Unfortunately, the absence of first-principle theoretical guidance has made this a formidable challenge. The state-of-the-art simulation tool, Geant4, currently relies on phenomenology-inspired parametric models. Each model is designed to simulate hadronic interactions within specific energy ranges and for particular types of hadrons. Despite dedicated tuning efforts, these models sometimes fail to describe the data in certain physics processes accurately. Furthermore, finetuning these models with new measurements is laborious. Our research endeavors to leverage generative models to simulate hadronic interactions. While our ultimate goal is to train a generative model using experimental data, we have taken a crucial step by training conditional normalizing flow models with Geant4 simulation data. Our work marks a significant stride toward developing a fully differentiable and data-driven model for hadronic interactions in High Energy and Nuclear Physics. [ABSTRACT FROM AUTHOR]

Published

2024

36. Transformers for Generalized Fast Shower Simulation.

Author

Raikwar, Piyush, Cardoso, Renato, Chernyavskaya, Nadezda, Jaruskova, Kristina, Pokorski, Witold, Salamani, Dalila, Srivatsa, Mudhakar, Tsolaki, Kalliopi, Vallecorsa, Sofia, and Zaborowska, Anna

Subjects

*COMPUTER simulation, *INTERPOLATION, *EXTRAPOLATION, *PARTICLE detectors, *CALORIMETERS

Abstract

Recently, transformer-based foundation models have proven to be a generalized architecture applicable to various data modalities, ranging from text to audio and even a combination of multiple modalities. Transformers by design should accurately model the non-trivial structure of particle showers thanks to the absence of strong inductive bias, better modeling of long-range dependencies, and interpolation and extrapolation capabilities. In this paper, we explore a transformer-based generative model for detector-agnostic fast shower simulation, where the goal is to generate synthetic particle showers, i.e., the energy depositions in the calorimeter. When trained with an adequate amount and variety of showers, these models should learn better representations compared to other deep learning models, and hence should quickly adapt to new detectors. In this work, we will show the prototype of a transformer-based generative model for fast shower simulation, as well as explore certain aspects of transformer architecture such as input data representation, sequence formation, and the learning mechanism for our unconventional shower data. [ABSTRACT FROM AUTHOR]

Published

2024

37. What Machine Learning Can Do for Focusing Aerogel Detectors.

Author

Shipilov, Foma, Barnyakov, Alexander, Bobrovnikov, Vladimir, Kononov, Sergey, and Ratnikov, Fedor

Subjects

*MACHINE learning, *PARTICLE detectors, *AEROGELS, *CHERENKOV counters, *COMPUTER vision

Abstract

Particle identification at the Super Charm-Tau factory experiment will be provided by a Focusing Aerogel Ring Imaging CHerenkov detector (FARICH). The specifics of detector location make proper cooling difficult, therefore a significant number of ambient background hits are captured. They must be mitigated to reduce the data flow and improve particle velocity resolution. In this work we present several approaches to filtering signal hits, inspired by machine learning techniques from computer vision. [ABSTRACT FROM AUTHOR]

Published

2024

38. Vertex reconstruction with Graph Neural Network in JSNS2.

Author

Yoo, Changhyun and Goh, Junghwan

Subjects

*ARTIFICIAL neural networks, *NEUTRINO oscillation, *PROTON beams, *PHOTOMULTIPLIERS, *PARTICLE detectors

Abstract

The JSNS2(J-PARC Sterile Neutrino Search at the J-PARC Spallation Neutron Source) experiment searches for neutrino oscillations at 24m baseline with the J-PARC's 3 GeV 1 MW proton beam incident on a mercury target at the Materials and Life science experimental Facility (MLF). The JSNS2detector consists of three cylindrical layers, an innermost neutrino target, an intermediate gamma-catcher, and an outermost veto. The neutrino target is made of 17 tonnes of Gd-loaded LS (Gd-LS) stored in an acrylic vessel, 3.2m(D) 2.5m(H). The detector consists of a total of 120 photomultiplier tubes (PMTs), 96 PMTs for inner and 24 PMTs for veto. In JSNS2, a maximum likelihood method based on the PMT charges is used to reconstruct position and energy of the event. We introduce Static Graph Convolution Neural Network (SGCNN), which is a combined model of PointNet and Graph Neural Network (GNN). The model was trained by Monte Carlo (MC) samples, and the position and charge of 96 inner PMTs was used as the training feature. [ABSTRACT FROM AUTHOR]

Published

2024

39. Deployment of ML in Changing Environments.

Author

Barbone, Marco, Brown, Christopher, Radburn-Smith, Benjamin, and Tapper, Alexander

Subjects

*MACHINE learning, *LARGE Hadron Collider, *FIELD programmable gate arrays, *PARTICLE detectors, *COMPACT muon solenoid experiment

Abstract

The High-Luminosity LHC upgrade of the CMS experiment will utilise a large number of Machine Learning (ML) based algorithms in its hardware-based trigger. These ML algorithms will facilitate the selection of potentially interesting events for storage and offline analysis. Strict latency and resource requirements limit the size and complexity of these models due to their use in a high-speed trigger setting and deployment on FPGA hardware. It is envisaged that these ML models will be trained on large, carefully tuned, Monte Carlo datasets and subsequently deployed in a real-world detector environment. Not only is there a potentially large difference between the MC training data and real-world conditions but these detector conditions could change over time leading to a shift in model output which could degrade trigger performance. The studies presented explore different techniques to reduce the impact of this effect, using the CMS track finding and vertex trigger algorithms as a test case. The studies compare a baseline retraining and redeployment of the model and episodic training of a model as new data arrives in a continual learning context. The results show that a continually learning algorithm outperforms a simple retrained model when degradation in detector performance is applied to the training data and is a viable option for maintaining performance in an evolving environment such as the High-Luminosity LHC. [ABSTRACT FROM AUTHOR]

Published

2024

40. Charged Track Reconstruction with Artificial Intelligence for CLAS12.

Author

Gavalian, Gagik, Thomadakis, Polykarpos, Angelopoulos, Angelos, and Chrisochoides, Nikos

Subjects

*ARTIFICIAL intelligence, *ARTIFICIAL neural networks, *DRIFT chambers, *PARTICLE detectors, *MULTILAYER perceptrons

Abstract

In this paper, we present the results of charged particle track reconstruction in CLAS12 using artificial intelligence. In our approach, we use neural networks working together to identify tracks based on the raw signals in the Drift Chambers. A Convolutional Auto-Encoder is used to de-noise raw data by removing the hits that do not satisfy the patterns for tracks, and second Multi-Layer Perceptron is used to identify tracks from combinations of clusters in the drift chambers. Our method increases the tracking efficiency by 50% for multi-particle final states already conducted experiments. The de-noising results indicate that future experiments can run at higher luminosity without degradation of the data quality. This in turn will lead to significant benefits for the CLAS12 physics program. [ABSTRACT FROM AUTHOR]

Published

2024

41. DeepTreeGAN: Fast Generation of High Dimensional Point Clouds.

Author

Scham, Moritz A.W., Krücker, Dirk, Käch, Benno, and Borras, Kerstin

Subjects

*POINT cloud, *PARTICLE physics, *PARTICLE detectors, *ARTIFICIAL neural networks, *COMPUTER simulation

Abstract

In High Energy Physics, detailed and time-consuming simulations are used for particle interactions with detectors. To bypass these simulations with a generative model, the generation of large point clouds in a short time is required, while the complex dependencies between the particles must be correctly modelled. Particle showers are inherently tree-based processes, as each particle is produced by the decay or detector interaction of a particle of the previous generation. In this work, we present a novel Graph Neural Network model (DeepTreeGAN) that is able to generate such point clouds in a tree-based manner. We show that this model can reproduce complex distributions, and we evaluate its performance on the public JetNet dataset. [ABSTRACT FROM AUTHOR]

Published

2024

42. Fast muon simulation in the JUNO experiment with neural networks.

Author

Fang, Wenxing, Li, Weidong, and Lin, Tao

Subjects

*ARTIFICIAL neural networks, *MUONS, *PHYSICS experiments, *NEUTRINO mass, *PARTICLE detectors

Abstract

The Jiangmen Underground Neutrino Observatory (JUNO) experiment is set to begin data taking in 2024 with the aim of determining the neutrino mass ordering (NMO) to a significance of 3 σ after 6 years of data taking. Achieving this goal requires effective background suppression, with the background induced by cosmic-ray muons being one of the most significant sources of interference in the NMO study. Accurately simulating the cosmic-ray muon background is crucial for the success of the experiment, but the sheer number of optical photons produced by the muon makes this detector simulation process extremely time-consuming using traditional methods such as Geant4. This paper presents a fast muon simulation method that employs neural networks to expedite the simulation process. Our approach achieves an order-of-magnitude speed-up in simulation time compared to Geant4, while still producing accurate results. [ABSTRACT FROM AUTHOR]

Published

2024

43. Refining fast simulation using machine learning.

Author

Bein, Samuel, Connor, Patrick, Pedro, Kevin, Schleper, Peter, and Wolf, Moritz

Subjects

*MACHINE learning, *COMPACT muon solenoid experiment, *PARTICLE detectors, *MONTE Carlo method, *LOSS functions (Statistics)

Abstract

At the CMS experiment, a growing reliance on the fast Monte Carlo application (FastSim) will accompany the high luminosity and detector granularity expected in Phase 2. The FastSim chain is roughly 10 times faster than the application based on the Geant4 detector simulation and full reconstruction referred to as FullSim. However, this advantage comes at the price of decreased accuracy in some of the final analysis observables. In this contribution, a machine learning-based technique to refine those observables is presented. We employ a regression neural network trained with a sophisticated combination of multiple loss functions to provide post-hoc corrections to samples produced by the FastSim chain. The results show considerably improved agreement with the FullSim output and an improvement in correlations among output observables and external parameters. This technique is a promising replacement for existing correction factors, providing higher accuracy and thus contributing to the wider usage of FastSim. [ABSTRACT FROM AUTHOR]

Published

2024

44. The Neutron-Gamma Pulse Shape Discrimination of CLLB Detector.

Author

Song, Ruiqiang, Peng, Shuo, Tong, Yufeng, Wu, Qi, Qian, Sen, Wang, Zhigang, and Han, Jifeng

Subjects

*PARTICLE detectors, *GAMMA rays, *NEUTRONS, *ARTIFICIAL neural networks, *IMAGE recognition (Computer vision)

Abstract

Cs2LiLaBr6: Ce (CLLB) scintillator with the size of Φ 21mm × 25 mm coupled with PMT was used to detect neutron and gamma rays. The pulse shape discrimination (PSD) of neutrons and gamma rays by charge comparison method, the neutrons and gamma rays from AmBe source and fast neutron beam can be separated with figure-of-merit (FOM) values of 0.9 and 1.3, respectively. However, some neutron and gamma rays are difficult to distinguish, so new algorithms need to be investigated to improve the PSD performance of neutron and gamma. Artificial neural networks (ANN) have a very good image recognition capability, thus the ANN model was constructed to discriminate the waveforms of neutron and gamma rays. After ANN model training, the neutron and gamma signals of the CLLB detector were recognized with an accuracy of 98%, and the FOM value of the ANN method was calculated to be 19.4. This result is much higher than the charge comparison method, indicating better discrimination between neutrons and gamma rays with the ANN method. [ABSTRACT FROM AUTHOR]

Published

2024

45. Particle identification with machine learning in ALICE Run 3.

Author

Karwowska, Maja, Jakubowska, Monika, Graczykowski, Łukasz, Deja, Kamil, and Kasak, Miłosz

Subjects

*PARTICLE physics, *MACHINE learning, *QUARK-gluon plasma, *PARTICLE detectors, *ARTIFICIAL neural networks

Abstract

The main focus of the ALICE experiment, quark–gluon plasma measurements, requires accurate particle identification (PID). The ALICE subdetectors allow identifying particles over a broad momentum interval ranging from about 100 MeV/c up to 20 GeV/c. However, a machine learning (ML) model can explore more detector information. During LHC Run 2, preliminary studies with Random Forests obtained much higher efficiencies and purities for selected particles than standard techniques. For Run 3, we investigate Domain Adaptation Neural Networks that account for the discrepancies between the Monte Carlo simulations and the experimental data. Preliminary studies show that domain adaptation improves particle classification. Moreover, the solution is extended with Feature Set Embedding and attention to give the network more flexibility to train on data with various sets of detector signals. PID ML is already integrated with the ALICE Run 3 Analysis Framework. Preliminary results for the PID of selected particle species, including real-world analyzes, are discussed as well as the possible optimizations. [ABSTRACT FROM AUTHOR]

Published

2024

46. Muon and Pion Identification at BESIII Based on Machine Learning Algorithm.

Author

Zhai, Yuncong, Li, Teng, Huang, Xingtao, and Yin, Na

Subjects

*MUONS, *PIONS, *MACHINE learning, *PHYSICS experiments, *PARTICLE detectors

Abstract

BESIII is designed to study physics in the τ-charm energy region utilizing the high luminosity BEPCII. For collision physics experiments like the BESIII experiment, particle identification (PID) is one of the most important and commonly used tools for physics analysis. The effective µ/π identification performance is of great significance for most of BESIII physics analysis. However, due to the close masses of these two particles, as well as the intrinsic correlation between multiple detector information, traditional methods at BESIII is facing challenges in µ/π identification. In recent decades, machine learning (ML) techniques have been rapidly developed and have shown successful applications in HEP experiments. The PID based on ML provides powerful capability of combining more detection information from all sub-detectors with the data-driven approach. In this article, targeting at the µ/π identification problem at the BESIII experiment, we have developed a new PID algorithm based on the gradient boosted decision tree (BDT) model. Preliminary results show that the XGBoost classifier provides obviously higher discrimination power than traditional methods. In addition, based on the substantial amount of high-quality data taken by the BESIII detector, a method of evaluating and suppressing the systematical error of the ML model is also introduced, which is critical for applying the model to physics studies. [ABSTRACT FROM AUTHOR]

Published

2024

47. Embedded Continual Learning for High-Energy Physics.

Author

Barbone, Marco, Brown, Christopher, Gaydadjiev, Georgi, Maguire, Thomas, Mieskolainen, Mikael, Radburn-Smith, Benjamin, Luk, Wayne, and Tapper, Alexander

Subjects

*PARTICLE physics, *ARTIFICIAL neural networks, *MACHINE learning, *PARTICLE detectors, *LARGE Hadron Collider

Abstract

Neural Networks (NN) are often trained offline on large datasets and deployed on specialised hardware for inference, with a strict separation between training and inference. However, in many realistic applications the training environment differs from the real world, or data arrives in a streaming fashion and is continuously changing. In these scenarios, the ability to continuously train and update NN models is desirable. Continual learning (CL) algorithms allow training of models on a stream of data. CL algorithms are often designed to work in constrained settings, such as limited memory and computational power, or limitations on the ability to store past data (e.g, due to privacy concerns or memory requirements). High-energy physics experiments are developing intelligent detectors, with algorithms running on computer systems located close to the detector to meet the challenges of increased data rates and occupancies. The use of NN algorithms in this context is limited by changing detector conditions, such as degradation over time or failure of an input signal which might cause the NNs to lose accuracy leading, in the worst case to the loss of interesting events. CL has the potential to solve this issue, using large amounts of continuously streaming data to allow the network to recognise changes, and to learn and adapt to detector conditions. It has the potential to outperform traditional NN training techniques as not all possible scenarios can be predicted and modelled in static training data samples. However, NN training is computationally expensive and when combined with the strict timing requirements of embedded processors deployed close to the detector, current state-of-the-art offline approaches cannot be directly applied to the real-time systems. Alternatives to typical backpropagation-based training that can be deployed on FPGAs for real-time data processing are presented, and their computational and accuracy characteristics are discussed in the context of High-Luminosity LHC. [ABSTRACT FROM AUTHOR]

Published

2024

48. End-to-end deep learning inference with CMSSW via ONNX using Docker.

Author

Chaudhari, Purva, Chaudhari, Shravan, Chudasama, Ruchi, and Gleyzer, Sergei

Subjects

*PARTICLE physics, *PARTICLE detectors, *DEEP learning, *COMPACT muon solenoid experiment, *GRAPHICS processing units

Abstract

Deep learning techniques have been proven to provide excellent performance for a variety of high-energy physics applications, such as particle identification, event reconstruction and trigger operations. Recently, we developed an end-to-end deep learning approach to identify various particles using low-level detector information from high-energy collisions. These models will be incorporated in the CMS software framework (CMSSW) to enable their use for particle reconstruction or for trigger operation in real time. Incorporating these computational tools in the experimental framework presents new challenges. This paper reports an implementation of the end-to-end deep learning inference with the CMS software framework. The inference has been implemented on GPU for faster computation using ONNX. We have benchmarked the ONNX inference with GPU and CPU using NERSC's Perlmutter cluster by building a Docker image of the CMS software framework. [ABSTRACT FROM AUTHOR]

Published

2024

49. A method for inferring signal strength modifiers by conditional invertible neural networks.

Author

Farkas, Máté Zoltán, Diekmann, Svenja, Eich, Niclas, and Erdmann, Martin

Subjects

*ARTIFICIAL neural networks, *PARTICLE physics, *COLLIDERS (Nuclear physics), *PARTICLE detectors, *ARTIFICIAL intelligence

Abstract

The continuous growth in model complexity in high-energy physics (HEP) collider experiments demands increasingly time-consuming model fits. We show first results on the application of conditional invertible networks (cINNs) to this challenge. Specifically, we construct and train a cINN to learn the mapping from signal strength modifiers to observables and its inverse. The resulting network infers the posterior distribution of the signal strength modifiers rapidly and for low computational cost. We present performance indicators of such a setup including the treatment of systematic uncertainties. Additionally, we highlight the features of cINNs estimating the signal strength for a vector boson associated Higgs production analysis of simulated samples of events, which include a simulation of the CMS detector. [ABSTRACT FROM AUTHOR]

Published

2024

50. Sharing ATLAS Science: Communicating to the Public.

Author

Le Boulicaut Ennis, Elise

Subjects

*PHYSICS experiments, *DIGITAL communications, *SOCIAL media, *WEBSITES, *PARTICLE detectors

Abstract

Communicating the science and achievements of the ATLAS Experiment is a core objective of the ATLAS Collaboration. This contribution will explore the range of communication strategies adopted by ATLAS. In particular, an overview of ATLAS' digital communication platforms will be given, including the ATLAS website, social media, Virtual Visits, and Open Data. [ABSTRACT FROM AUTHOR]

Published

2024