Your search keyword '"Matteo Duranti"' showing total 8 results

1. Advances in Space Astroparticle Physics: Frontier Technologies for Particle Measurements in Space

Author

Matteo Duranti and Valerio Vagelli

Subjects

n/a, Physics, QC1-999, Nuclear and particle physics. Atomic energy. Radioactivity, QC770-798

Abstract

In the last decades, breakthrough advances in understanding the mechanisms of the Universe and fundamental physics have been achieved through the exploitation of data on cosmic rays and high-energy radiation gathered via orbiting experiments, in a synergic and complementary international effort that combines space-based instrument data with ground-based space observatories, accelerator, and collider experiments [...]

Published

2024

2. Real-Time Monitoring of Solar Energetic Particles Using the Alpha Magnetic Spectrometer on the International Space Station

Author

Andrea Serpolla, Matteo Duranti, Valerio Formato, and Alberto Oliva

Subjects

cosmic rays, solar energetic particles, space weather, Physics, QC1-999, Nuclear and particle physics. Atomic energy. Radioactivity, QC770-798

Abstract

The International Space Station (ISS) orbits at an average altitude of 400 km, in the Low Earth Orbit (LEO) and is regularly occupied by astronauts. The material of the Station, the residual atmosphere and the geomagnetic field offer a partial protection against the cosmic radiation to the crew and the equipment. The solar activity can cause sporadic bursts of particles with energies between ∼10 keV and several GeVs called Solar Energetic Particles (SEPs). SEP emissions can last for hours or even days and can represent an actual risk for ISS occupants and equipment. The Alpha Magnetic Spectrometer (AMS) was installed on the ISS in 2011 and is expected to take data until the decommissioning of the Station itself. The instrument detects cosmic rays continuously and can also be used to monitor SEPs in real-time. A detection algorithm developed for the monitoring measures temporary increases in the trigger rates of AMS, using McIlwain’s L-parameter to characterize different conditions of the data-taking environment. A real-time monitor for SEPs has been realized reading data from the AMS Monitoring Interface (AMI) database and processing them using the custom algorithm that was developed.

Published

2023

3. Tracker-in-Calorimeter (TIC) Project: A Calorimetric New Solution for Space Experiments

Author

Gabriele Bigongiari, Oscar Adriani, Giovanni Ambrosi, Philipp Azzarello, Andrea Basti, Eugenio Berti, Bruna Bertucci, Lorenzo Bonechi, Massimo Bongi, Sergio Bottai, Mirko Brianzi, Paolo Brogi, Guido Castellini, Enrico Catanzani, Caterina Checchia, Raffaello D’Alessandro, Sebastiano Detti, Matteo Duranti, Noemi Finetti, Valerio Formato, Maria Ionica, Paolo Maestro, Fernando Maletta, Pier Simone Marrocchesi, Nicola Mori, Lorenzo Pacini, Paolo Papini, Sergio Bruno Ricciarini, Gianluigi Silvestre, Piero Spillantini, Oleksandr Starodubtsev, Francesco Stolzi, Jung Eun Suh, Arta Sulaj, Alessio Tiberio, and Elena Vannuccini

Subjects

cosmic rays, astroparticles, γ-ray astronomy, Physics, QC1-999, Nuclear and particle physics. Atomic energy. Radioactivity, QC770-798

Abstract

A space-based detector dedicated to measurements of γ-rays and charged particles has to achieve a balance between different instrumental requirements. A good angular resolution is necessary for the γ-rays, whereas an excellent geometric factor is needed for the charged particles. The tracking reference technique of γ-ray physics is based on a pair-conversion telescope made of passive material (e.g., tungsten) coupled with sensitive layers (e.g., silicon microstrip). However, this kind of detector has a limited acceptance because of the large lever arm between the active layers, needed to improve the track reconstruction capability. Moreover, the passive material can induce fragmentation of nuclei, thus worsening charge reconstruction performances. The Tracker-In-Calorimeter (TIC) project aims to solve all these drawbacks. In the TIC proposal, the silicon sensors are moved inside a highly-segmented isotropic calorimeter with a couple of external scintillators dedicated to charge reconstruction. In principle, this configuration has a good geometrical factor, and the angle of the γ-rays can be precisely reconstructed from the lateral profile of the electromagnetic shower sampled, at different depths in the calorimeter, by silicon strips. The effectiveness of this approach has been studied with Monte Carlo simulations and validated with beam test data of a small prototype.

Published

2022

4. Design of an Antimatter Large Acceptance Detector In Orbit (ALADInO)

Author

Oscar Adriani, Corrado Altomare, Giovanni Ambrosi, Philipp Azzarello, Felicia Carla Tiziana Barbato, Roberto Battiston, Bertrand Baudouy, Benedikt Bergmann, Eugenio Berti, Bruna Bertucci, Mirko Boezio, Valter Bonvicini, Sergio Bottai, Petr Burian, Mario Buscemi, Franck Cadoux, Valerio Calvelli, Donatella Campana, Jorge Casaus, Andrea Contin, Raffaello D’Alessandro, Magnus Dam, Ivan De Mitri, Francesco de Palma, Laurent Derome, Valeria Di Felice, Adriano Di Giovanni, Federico Donnini, Matteo Duranti, Emanuele Fiandrini, Francesco Maria Follega, Valerio Formato, Fabio Gargano, Francesca Giovacchini, Maura Graziani, Maria Ionica, Roberto Iuppa, Francesco Loparco, Jesús Marín, Samuele Mariotto, Giovanni Marsella, Gustavo Martínez, Manel Martínez, Matteo Martucci, Nicolò Masi, Mario Nicola Mazziotta, Matteo Mergé, Nicola Mori, Riccardo Munini, Riccardo Musenich, Lorenzo Mussolin, Francesco Nozzoli, Alberto Oliva, Giuseppe Osteria, Lorenzo Pacini, Mercedes Paniccia, Paolo Papini, Mark Pearce, Chiara Perrina, Piergiorgio Picozza, Cecilia Pizzolotto, Stanislav Pospíšil, Michele Pozzato, Lucio Quadrani, Ester Ricci, Javier Rico, Lucio Rossi, Enrico Junior Schioppa, Davide Serini, Petr Smolyanskiy, Alessandro Sotgiu, Roberta Sparvoli, Antonio Surdo, Nicola Tomassetti, Valerio Vagelli, Miguel Ángel Velasco, Xin Wu, and Paolo Zuccon

Subjects

cosmic rays, antimatter, dark matter, particle detectors, space instrumentation, Physics, QC1-999, Nuclear and particle physics. Atomic energy. Radioactivity, QC770-798

Abstract

A new generation magnetic spectrometer in space will open the opportunity to investigate the frontiers in direct high-energy cosmic ray measurements and to precisely measure the amount of the rare antimatter component in cosmic rays beyond the reach of current missions. We propose the concept for an Antimatter Large Acceptance Detector In Orbit (ALADInO), designed to take over the legacy of direct measurements of cosmic rays in space performed by PAMELA and AMS-02. ALADInO features technological solutions conceived to overcome the current limitations of magnetic spectrometers in space with a layout that provides an acceptance larger than 10 m2 sr. A superconducting magnet coupled to precision tracking and time-of-flight systems can provide the required matter–antimatter separation capabilities and rigidity measurement resolution with a Maximum Detectable Rigidity better than 20 TV. The inner 3D-imaging deep calorimeter, designed to maximize the isotropic acceptance of particles, allows for the measurement of cosmic rays up to PeV energies with accurate energy resolution to precisely measure features in the cosmic ray spectra. The operations of ALADInO in the Sun–Earth L2 Lagrangian point for at least 5 years would enable unique revolutionary observations with groundbreaking discovery potentials in the field of astroparticle physics by precision measurements of electrons, positrons, and antiprotons up to 10 TeV and of nuclear cosmic rays up to PeV energies, and by the possible unambiguous detection and measurement of low-energy antideuteron and antihelium components in cosmic rays.

Published

2022

5. Advantages and Requirements in Time Resolving Tracking for Astroparticle Experiments in Space

Author

Matteo Duranti, Valerio Vagelli, Giovanni Ambrosi, Mattia Barbanera, Bruna Bertucci, Enrico Catanzani, Federico Donnini, Francesco Faldi, Valerio Formato, Maura Graziani, Maria Ionica, Lucio Moriconi, Alberto Oliva, Andrea Serpolla, Gianluigi Silvestre, and Luca Tosti

Subjects

silicon detectors, trackers, timing, LGAD, astroparticle detectors in space, Physics, QC1-999, Nuclear and particle physics. Atomic energy. Radioactivity, QC770-798

Abstract

A large-area, solid-state detector with single-hit precision timing measurement will enable several breakthrough experimental advances for the direct measurement of particles in space. Silicon microstrip detectors are the most promising candidate technology to instrument the large areas of the next-generation astroparticle space borne detectors that could meet the limitations on power consumption required by operations in space. We overview the novel experimental opportunities that could be enabled by the introduction of the timing measurement, concurrent with the accurate spatial and charge measurement, in Silicon microstrip tracking detectors, and we discuss the technological solutions and their readiness to enable the operations of large-area Silicon microstrip timing detectors in space.

Published

2021

6. A New Approach to Calorimetry in Space-Based Experiments for High-Energy Cosmic Rays

Author

Gabriele Bigongiari, Oscar Adriani, Sebastiano Albergo, Giovanni Ambrosi, Lucrezia Auditore, Andrea Basti, Eugenio Berti, Lorenzo Bonechi, Simone Bonechi, Massimo Bongi, Valter Bonvicini, Sergio Bottai, Paolo Brogi, Gigi Cappello, Paolo Walter Cattaneo, Raffaello D’Alessandro, Sebastiano Detti, Matteo Duranti, Mauro Fasoli, Noemi Finetti, Valerio Formato, Maria Ionica, Antonio Italiano, Piergiulio Lenzi, Paolo Maestro, Pier Simone Marrocchesi, Nicola Mori, Giulio Orzan, Miriam Olmi, Lorenzo Pacini, Paolo Papini, Maria Grazia Pellegriti, Andrea Rappoldi, Sergio Bruno Ricciarini, Antonella Sciuto, Gianluigi Silvestre, Oleksandr Starodubtsev, Francesco Stolzi, Jung Eun Suh, Arta Sulaj, Alessio Tiberio, Alessia Tricomi, Antonio Trifirò, Marina Trimarchi, Elena Vannuccini, Anna Vedda, Gianluigi Zampa, and Nicola Zampa

Subjects

cosmic rays, astroparticles, γ -ray astronomy, Elementary particle physics, QC793-793.5

Abstract

Precise measurements of the energy spectra and of the composition of cosmic rays in the PeV region could improve our knowledge regarding their origin, acceleration mechanism, propagation, and composition. At the present time, spectral measurements in this region are mainly derived from data collected by ground-based detectors, because of the very low particle rates at these energies. Unfortunately, these results are affected by the high uncertainties typical of indirect measurements, which depend on the complicated modeling of the interaction of the primary particle with the atmosphere. A space experiment dedicated to measurements in this energy region has to achieve a balance between the requirements of lightness and compactness, with that of a large acceptance to cope with the low particle rates. CaloCube is a four-year-old R&D project, approved and financed by the Istituto Nazionale di Fisica Nucleare (INFN) in 2014, aiming to optimize the design of a space-borne calorimeter. The large acceptance needed is obtained by maximizing the number of entrance windows, while thanks to its homogeneity and high segmentation this new detector achieves an excellent energy resolution and an enhanced separation power between hadrons and electrons. In order to optimize detector performances with respect to the total mass of the apparatus, comparative studies on different scintillating materials, different sizes of crystals, and different spacings among them have been performed making use of MonteCarlo simulations. In parallel to simulations studies, several prototypes instrumented with CsI(Tl) (Caesium Iodide, Tallium doped) cubic crystals have been constructed and tested with particle beams. Moreover, the last development of CaloCube, the Tracker-In-Calorimeter (TIC) project, financed by the INFN in 2018, is focused on the feasibility of including several silicon layers at different depths in the calorimeter in order to reconstruct the particle direction. In fact, an important requirement for γ -ray astronomy is to have a good angular resolution in order to allow precise identification of astrophysical sources in space. In respect to the traditional approach of using a tracker with passive material in front of the calorimeter, the TIC solution can save a significant amount of mass budget in a space satellite experiment, which can then be exploited to improve the acceptance and the resolution of the calorimeter. In this paper, the status of the project and perspectives for future developments are presented.

Published

2019

7. A flexible and modular data format ROOT-based implementation for HEP.

Author

Domenico D'Urso and Matteo Duranti

Published

2015

8. An integrated solution for remote data access.

Author

Vladimir Sapunenko, Domenico D'Urso, Luca dell'Agnello, Vincenzo Vagnoni, and Matteo Duranti

Published

2015