Your search keyword '"Cozzolino, Fabio"' showing total 11 results

1. Development and testing of the MicroMED sensor: From BreadBoard model to flight model

Author

Cozzolino, Fabio, Franzese, Gabriele, Cortecchia, Fausto, Molfese, Cesare, Esposito, Francesca, Mongelluzzo, Giuseppe, Ruggeri, Alan Cosimo, Porto, Carmen, Silvestro, Simone, Popa, Ciprian Ionut, Scaccabarozzi, Diego, Saggin, Bortolino, Arruego, Ignacio, De Mingo, José Ramon, Rico, Alberto Martín-Ortega, Andrés-Santiuste, Nuria, Rivas, Joaquìn, and Brienza, Daniele

Published

2024

2. Structural Optimization of MicroMED Dust Analyzer

Author

Corti, Marco Giovanni, primary, Saggin, Bortolino, additional, Esposito, Francesca, additional, Franzese, Gabriele, additional, Porto, Carmen, additional, Mongelluzzo, Giuseppe, additional, Cozzolino, Fabio, additional, and Scaccabarozzi, Diego, additional

Published

2023

3. Dispositivo e metodo per il campionamento e la rilevazione di un agente patogeno nell'aria

Author

Caputo, Domenico, Nascetti, Augusto, DE CESARE, Giampiero, Costantini, Francesca, Lovecchio, Nicola, Iannascoli, Lorenzo, Esposito, Francesca, Brucato John Robert, Cozzolino, Fabio, Mongelluzzo, Giuseppe, Popa Ciprian Ionut, Fornaro, Teresa, Meneghin, Andrea, Paglialunga, Daniele, Pareschi, Giovanni, Mirasoli, Mara, Michelini, Elisa, Guardigli, Massimo, Clerici, Mario, Trabattoni, Daria, Biasin, Mara, and Scaccabarozzi, Diego.

Subjects

Sicurezza sul lavoro, Lab-on-Chip, COVID 19, Controllo qualità dell’aria

Published

2020

4. “MicroMED” Optical Particle Counter: From Design to Flight Model

Author

Scaccabarozzi, Diego, primary, Saggin, Bortolino, additional, Somaschini, Riccardo, additional, Magni, Marianna, additional, Valnegri, Pietro, additional, Esposito, Francesca, additional, Molfese, Cesare, additional, Cozzolino, Fabio, additional, and Mongelluzzo, Giuseppe, additional

Published

2020

5. Design and CFD Analysis of the Fluid Dynamic Sampling System of the “MicroMED” Optical Particle Counter

Author

Mongelluzzo, Giuseppe, primary, Esposito, Francesca, additional, Cozzolino, Fabio, additional, Franzese, Gabriele, additional, Ruggeri, Alan Cosimo, additional, Porto, Carmen, additional, Molfese, Cesare, additional, Scaccabarozzi, Diego, additional, and Saggin, Bortolino, additional

Published

2019

6. MicroMED: an optical particle counter for the direct in situ measurement of abundance and size distribution of dust suspended in the atmosphere of Mars

Author

ESPOSITO, Francesca, COZZOLINO, Fabio, MOLFESE, CESARE, CORTECCHIA, Fausto, Saggin, B., D'Amato, F., and ITA

Abstract

The MicroMED experiment has been developed for the characterization of airborne dust close to the surface of Mars and is suitable to be accommodated on Martian landers or rovers. It is an optical particle counter, analyzing light scattered from single dust particles to measure their size and abundance. An Elegant Breadboard of the instrument has been realized and successfully tested in a Martian simulated environment. Test results demonstrate the expected functionality and performances of the experiment.

Published

2015

7. Progettazione e Sviluppo di un sistema di GSE per il controllo di sensori per applicazioni spaziali. Test e analisi di un rivelatore compatto di polveri per l'ambiente Marziano

Author

Cozzolino, Fabio and Cozzolino, Fabio

Abstract

Lo sviluppo dello strumento MicroMED ha previsto la progettazione, la realizzazione e i test di un optical particle counter di dimensioni 40 x 36 x 43 mm con basso consumo (1 W) e massa ridotta (500 g), capace di misurare la distribuzione dimensionale e la densità numerica delle polveri in sospensione nell'atmosfera marziana, in vicinanza della superficie e con un intervallo di misura compreso tra 0.2 e 10 µm di raggio. MicroMED è stato progettato per aspirare le particelle situate in sospensione nell'atmosfera di Marte, indirizzarle verso una piccola regione (volume di campionamento) posta all'interno dello strumento e illuminata da un sistema ottico, e determinarne le dimensioni. Sono stati realizzati due prototipi dello strumento. Il primo modello è costituito dalla sola scatola dello strumento, di cui sono state riprodotte fedelmente le dimensioni interne come da disegno, oltre ai condotti di aspirazione (inlet) e di scarico (outlet) e alla pompa. E' stato utilizzato per caratterizzare gli aspetti fluidodinamici del sensore. Il secondo prototipo contiene anche il sistema ottico e l'elettronica di prossimità ed è stato utilizzato per i test funzionali e di calibrazione. Sono stati eseguiti diversi test atti a dimostrare la funzionalità e le prestazioni dell'esperimento. I test che hanno riguardato gli aspetti fluidodinamici di MicroMED hanno avuto lo scopo di verificare il sistema di aspirazione, il regime del flusso (turbolento o laminare) e studiare il moto delle particelle nel flusso. I risultati hanno indicato che MicroMED è capace di aspirare particelle nell'intervallo dimensionale richiesto (0.4-20 m), che il regime del flusso è laminare e che le particelle subiscono una deviazione rispetto alla linea centrale del flusso aspirato dipendente dalla loro dimensione. Tali deviazioni sono comunque minori della dimensione del volume di campionamento per cui tutte le particelle in transito all'interno dello strumento possono essere rilevate. I test hanno conferma

Published

2015

8. Recent replenishment of aliphatic organics on Ceres from a large subsurface reservoir.

Author

Cristina De Sanctis, Maria, Baratta, Giuseppe A., Brucato, John R., Castillo-Rogez, Julie, Ciarniello, Mauro, Cozzolino, Fabio, De Angelis, Simone, Ferrari, Marco, Fulvio, Daniele, Germanà, Massimo, Mennella, Vito, Pagnoscin, Silvia, Palumbo, Maria Elisabetta, Poggiali, Giovanni, Popa, Ciprian, Raponi, Andrea, Scirè, Carlotta, Strazzulla, Giovanni, and Urso, Riccardo Giovanni

Subjects

*ORBITS (Astronomy), *CHONDRITES, *SURFACE area, *RADIATION

Abstract

Ceres hosts notable aliphatic-organic concentrations, ranging from approximately 5 to >30 weight % in specific surface areas. The origins and persistence of these organics are under debate due to the intense aliphatic organic signature and radiation levels in Ceres' orbit, which would typically lead to their destruction, hindering detection. To investigate this, we conducted laboratory experiments to replicate how the signature of the organic-rich regions would degrade due to radiation. Our findings indicate a fast degradation rate, implying the exposure of buried organics within the past few million years. This degradation rate, coupled with observed quantities, implies that the aliphatics must be present in substantial quantities within the shallow subsurface. Our estimates suggest an initial aliphatic abundance 2 to 30 times greater than currently observed, surpassing significantly the levels found in carbonaceous chondrites, indicating either a significant concentration or remarkable purity. [ABSTRACT FROM AUTHOR]

Published

2024

9. MicroMED: a dust particle counter for the characterization of airborne dust close to the surface of Mars

Author

Cozzolino, Fabio, Francesca Esposito, Molfese, Cesare, Cortecchia, Fausto, Saggin, Bortolino, D Amato, Francesco, and ITA

Subjects

Astrophysics::Solar and Stellar Astrophysics, Astrophysics::Cosmology and Extragalactic Astrophysics, Astrophysics::Earth and Planetary Astrophysics, Physics::Atmospheric and Oceanic Physics, Astrophysics::Galaxy Astrophysics

Abstract

Monitoring of airborne dust is very important in planetary climatology. Indeed, dust absorbs and scatter solar and thermal radiation, severely affecting atmospheric thermal structure, balance and dynamics (in terms of circulations). Wind-driven blowing of sand and dust is also responsible for shaping planetary surfaces through the formation of sand dunes and ripples, the erosion of rocks, and the creation and transport of soil particles. Dust is permanently present in the atmosphere of Mars and its amount varies with seasons. During regional or global dust storms, more than 80% of the incoming sunlight is absorbed by dust causing an intense atmospheric heating. Airborne dust is therefore a crucial climate component on Mars which impacts atmospheric circulations at all scales. Main dust parameters influencing the atmosphere heating are size distribution, abundance, albedo, single scattering phase function, imaginary part of the index of refraction. Moreover, major improvements of Mars climate models require, in addition to the standard meteorological parameters, quantitative information about dust lifting, transport and removal mechanisms. In this context, two major quantities need to be measured for the dust source to be understood: surface flux and granulometry. While many observations have constrained the size distribution of the dust haze seen from the orbit, it is still not known what the primary airborne dust (e.g. the recently lifted dust) is made of, size-wise. MicroMED has been designed to fill this gap. It will measure the abundance and size distribution of dust, not in the atmospheric column, but close to the surface, where dust is lifted, so to be able to monitor dust injection into the atmosphere. This has never been performed in Mars and other planets exploration. MicroMED is an Optical Particle Counter, analyzing light scattered from single dust particles to measure their size and abundance. A proper fluid-dynamic system, including a pump and a sampling head, allows the sampling of Martian atmosphere with embedded dust. The captured dust grains are detected by an Optical System and then ejected into the atmosphere. MicroMED is a miniaturization of the instrument MEDUSA, developed for the Humboldt payload of the ExoMars mission. An Elegant Breadboard has been developed and tested and successfully demonstrates the instrument performances. The design and performance test results will be discussed.

10. The effect of dust lifting process on the electrical properties of the atmosphere

Author

Esposito, Francesca, Molinaro, Roberto, Ionut Popa, Ciprian, Molfese, Cesare, Cozzolino, Fabio, Marty, Laurent, Taj-Eddine, Kamal, Gaetano Di Achille, Silvestro, Simone, and Ori, Gian Gabriele

Subjects

Physics::Space Physics, Astrophysics::Solar and Stellar Astrophysics, Astrophysics::Earth and Planetary Astrophysics, Physics::Atmospheric and Oceanic Physics, Physics::Geophysics

Abstract

Airborne dust and aerosol particles affect climate by absorbing and scattering thermal and solar radiation and acting as condensation nuclei for the formation of clouds. So, they strongly influence the atmospheric thermal structure, balance and circulation. On Earth and Mars, this 'climate forcing' is one of the most uncertain processes in climate change predictions. Wind-driven blowing of sand and dust is also responsible for shaping planetary surfaces through the formation of sand dunes and ripples, the erosion of rocks, and the creation and transport of soil particles. These processes are not confined to Earth, but occur also on Mars, Venus and Titan. It is clear that the knowledge of the atmospheric dust properties and the mechanisms of dust settling and raising into the atmosphere are important to understand planetary climate and surface evolution. On Mars the physical processes responsible for dust injection into the atmosphere are still poorly understood, but they likely involve saltation as on Earth. Saltation is a process where large sand grains are forced by the wind to move in ballistic trajectories on the soil surface. During these hops they hit dust particles, that are well bound to the soil due to interparticle cohesive forces, thus transferring to them the momentum necessary to be entrained into the atmosphere. Recently, it has been shown that this process is also responsible to generate strong electric fields in the atmosphere up to 100-150 kV/m. This enhanced electric force acts as a feedback in the dust lifting process, lowering the threshold of the wind friction velocity u* necessary to initiate sand saltation. It is an important aspect of dust lifting process that need to be well characterized and modeled. Even if literature reports several measurements of E-fields in dust devils events, very few reports deal with atmospheric electric properties during dust storms or isolated gusts. We present here preliminary results of an intense field test campaign we performed in the West Sahara during the 2013 and 2014 dust storm seasons. We collected a statistical meaningful set of data characterizing relationship between dust lifting and atmospheric E-field that had never been achieved so far.

11. Performance assessment of an innovative light and compact dust shield for DISC onboard Comet Interceptor/ESA space probes.

Author

Della Corte, Vincenzo, Ferretti, Stefano, Piccirillo, Alice Maria, Rotundi, Alessandra, Bertini, Ivano, Cozzolino, Fabio, Ferone, Alessio, Fiscale, Stefano, Longobardo, Andrea, Inno, Laura, Ammannito, Eleonora, Sindoni, Giuseppe, Grappasonni, Chiara, Sylvest, Matthew, Patel, Manish R., Ertel, Hanno, Millinger, Mark, and Rothkaehl, Hanna

Subjects

*SPACE probes, *MOMENTUM transfer, *SOLAR system, *HYPERVELOCITY, *KINETIC energy, *COMETS, *CHURYUMOV-Gerasimenko comet, *DUST

Abstract

The dust ejected by cometary nuclei encodes valuable information on the formation and evolution of the early Solar System. Multiple short-period comets have been studied in situ, but several perihelion passages considerably modified their pristine condition. Comet Interceptor is the first space mission selected by the European Space Agency to study a pristine dynamically new comet in situ. During a fast flyby through the comet coma, hypervelocity impacts with dust particles will represent not only an important source of information, but also a serious hazard to the spacecraft and its payload. Here we discuss the assessment tests performed on the dust shield of the Dust Impact Sensor and Counter instrument (DISC), part of the Comet Interceptor payload, which will be directly exposed to the cometary dust flux. Using a Light-Gas Gun, we shot mm-sized particles at ∼ 5 km/s, transferring momenta and kinetic energies representative of those foreseen for the mission. The impact effects on the DISC breadboard were compared to theoretical predictions by a ballistic limit equation for hypervelocity impacts. We find that, with a simple improvement in the dust shield design, DISC is compatible with the expected cometary environment. • Innovative dust shield for instrument onboard Comet Interceptor/ESA mission. • Dust shield, inspired by the Whipple shield, with aerogel as stuffing material. • Tests performed to verify the dust shield performance, using a Light-Gas Gun. [ABSTRACT FROM AUTHOR]

Published

2025