Greater Padova (Padua) Metropolitan Area
Dynamic experimental physicist with an advanced degree in experimental physics and extensive expertise in radiation detection spanning diverse applications including nuclear analytical techniques, industrial sectors, homeland security, and radiation monitoring. Proven track record in leading and contributing to R&D projects, adept at designing, developing, maintaining, and operating cutting-edge radiation detection systems with a focus on neutron and gamma radiation. Skilled in radiation transport simulations using industry-leading Monte Carlo codes such as MCNP6, GEANT4, and PENELOPE. Dedicated to producing high-quality technical reports and scientific publications driving advancements in radiation detection technology.
20 hours course of Geometrical optics for Orthoptics students (Department of Neuroscience - University of Padova)
Responsible of the gamma detection array of a neutron-based inspection system (RRTNIS) for cargo during integration and field tests (Port of Rijeka, Croatia). Numerical simulations (Monte Carlo) and proof-of-principle experiments of neutron inspection techniques based on the laser-plasma neutron beam. Radiation safety studies, with Monte Carlo simulations, using a laser-plasma based X-rays sources to be employed in a 3D tomography for cargo inspection. Development and characterization, using Monte Carlo simulations and laboratory tests, of compact systems focused on neutron/gamma detection with discrimination capabilities for supporting decommissioning and dismantling operations of nuclear facilities. Development and characterization of new 3D-printable (photocurable) siloxane-based scintillators (for charge particles) to be used for dosimetry applications in proton therapy treatments.
Development of a state-of-art neutron detector based on new plastic scintillators with neutron/gamma discrimination capabilities, using a readout based on a SiPM arrays.Experiments and Monte Carlo simulations. Applications in: neutron diagnostics of plasma fusion facilities, nuclear physics experiments and nuclear security and safeguards. Design, develop and characterize (experimentally and by Monte Carlo simulation with MCNP6 and GEANT4) a mobile system composed of an Unmanned Aerial Vehicle (UAV) equipped with a detection system able to identify radioactive contamination spread over an area. Neutron/gamma discrimination using plastics and CLLB scintillators. Digital nuclear electronics. Experimental tests of novel flexible polysiloxane scintillators (for gamma-rays, thermal and fast neutrons, and change particles), in terms of light yield, efficiency and pulse shape discrimination capability.
Design, modelling (Monte Carlo simulations), characterization and test in field of a prototype for non-intrusive inspection of cargo containers in the field of homeland security. Development of the gamma-ray detection system of the first Rapidly Relocatable Tagged Neutron Inspection System (RRTNIS). Design, assembly and characterization (by experiments and Monte Carlo simulations using MCNP6 and GEANT4) of the set of gamma-ray detectors, and also, installation and optimization of the digital processing electronics. Responsible of the gamma detection system of the RRTNIS during integration and field tests (Port of Rotterdam, The Netherlands).
Monte Carlo modeling, with GEANT4, of a cosmic neutron detection system for estimation of water content in the soil (for optimization of water resources in agriculture).
Monte Carlo modeling, with GEANT4, of a multiphase flow metering to optimize the density measurement of the fluid in the oil and gas industry.