Physics, Astrophysics and Applied Physics
Doctoral programme (PhD)
A.Y. 2022/2023
Study area
Science and Technology
PhD Coordinator
The main theme of this doctoral programme is physics in advanced sectors of pure and applied research. Research covers all areas of modern physics, as indicated in the 5 curricula which aim to facilitate the placement of doctoral students in specific sectors.
The required basic training is guaranteed by a combination of courses specific to this programme and others exceptionally borrowed from the second cycle degree programme, with examinations at the end of the first year. Moreover, doctoratal students are required to attend an International School, with final assessment through a public seminar. The programme also provides various opportunities for discussion and exchanges among students in different programmes, particularly during a workshop at the end of the academic year.
Training is supplemented by coordinated series of subject- specific conferences ("Physics Colloquia"). At the same time, doctoral students will have to undertake original research under the guidance of a tutor and a co-tutor and report on their progress through annual seminars during which students present their findings to the University's scientific community. This programme also offers internships in Fundamental Physics or High Technology at National and International Laboratories and private Research Laboratories.
The required basic training is guaranteed by a combination of courses specific to this programme and others exceptionally borrowed from the second cycle degree programme, with examinations at the end of the first year. Moreover, doctoratal students are required to attend an International School, with final assessment through a public seminar. The programme also provides various opportunities for discussion and exchanges among students in different programmes, particularly during a workshop at the end of the academic year.
Training is supplemented by coordinated series of subject- specific conferences ("Physics Colloquia"). At the same time, doctoral students will have to undertake original research under the guidance of a tutor and a co-tutor and report on their progress through annual seminars during which students present their findings to the University's scientific community. This programme also offers internships in Fundamental Physics or High Technology at National and International Laboratories and private Research Laboratories.
Classi di laurea magistrale - Classes of master's degrees:
LM-6 Biologia,
LM-8 Biotecnologie industriali,
LM-9 Biotecnologie mediche, veterinarie e farmaceutiche,
LM-11 Scienze per la conservazione dei beni culturali,
LM-17 Fisica,
LM-18 Informatica,
LM-20 Ingegneria aerospaziale e astronautica,
LM-21 Ingegneria biomedica,
LM-22 Ingegneria chimica,
LM-25 Ingegneria dell'automazione,
LM-27 Ingegneria delle telecomunicazioni,
LM-28 Ingegneria elettrica,
LM-29 Ingegneria elettronica,
LM-30 Ingegneria energetica e nucleare,
LM-32 Ingegneria informatica,
LM-33 Ingegneria meccanica,
LM-40 Matematica,
LM-44 Modellistica matematico-fisica per l'ingegneria,
LM-53 Scienza e ingegneria dei materiali,
LM-54 Scienze chimiche,
LM-58 Scienze dell'universo,
LM-71 Scienze e tecnologie della chimica industriale,
LM-74 Scienze e tecnologie geologiche,
LM-75 Scienze e tecnologie per l'ambiente e il territorio,
LM-79 Scienze geofisiche,
LM-82 Scienze statistiche.
LM-6 Biologia,
LM-8 Biotecnologie industriali,
LM-9 Biotecnologie mediche, veterinarie e farmaceutiche,
LM-11 Scienze per la conservazione dei beni culturali,
LM-17 Fisica,
LM-18 Informatica,
LM-20 Ingegneria aerospaziale e astronautica,
LM-21 Ingegneria biomedica,
LM-22 Ingegneria chimica,
LM-25 Ingegneria dell'automazione,
LM-27 Ingegneria delle telecomunicazioni,
LM-28 Ingegneria elettrica,
LM-29 Ingegneria elettronica,
LM-30 Ingegneria energetica e nucleare,
LM-32 Ingegneria informatica,
LM-33 Ingegneria meccanica,
LM-40 Matematica,
LM-44 Modellistica matematico-fisica per l'ingegneria,
LM-53 Scienza e ingegneria dei materiali,
LM-54 Scienze chimiche,
LM-58 Scienze dell'universo,
LM-71 Scienze e tecnologie della chimica industriale,
LM-74 Scienze e tecnologie geologiche,
LM-75 Scienze e tecnologie per l'ambiente e il territorio,
LM-79 Scienze geofisiche,
LM-82 Scienze statistiche.
Dipartimento di Fisica "Aldo Pontremoli" - Via Celoria, 16 - Milano
- Main offices
Dipartimento di Fisica "Aldo Pontremoli" - Via Celoria, 16 - Milano - Degree course coordinator: prof. Matteo Paris
[email protected] - Degree course website
http://phd.fisica.unimi.it/
| Title | Professor(s) |
|---|---|
| Ground-based observations of polarized microwave emissions for galactic foregrounds removal from Cosmic Microwave Background data.
Curriculum: Astrophysics |
|
| Measuring the Cosmic Microwave Background with bolometric interferometry.
Curriculum: Astrophysics |
|
| Advanced instruments for Cosmic Microwave Background polarization measurements.
Curriculum: Astrophysics |
|
| Numerical simulations of cosmological performances of future redshift surveys (Euclid, DESI); forward modelling and generation of fast simulations, also involving Machine Learning applications.
Requirements: M.sc. level knowledge of observational and theoretical Cosmology. Basic programming (python/c,c++/fortran). Curriculum: Astrophysics |
B. Granett
F. Tosone
|
| Numerical simulations of large-scale structure formation in the presence of dark energy and massive neutrinos. Ray-tracing studies of the gravitational lensing of temperature and polarization maps of the cosmic microwave background.
Requirements: M.sc. level knowledge of Theoretical and Observational Cosmology. Basics of neutrino physics. Basics of programming (python,c,c++,fortran) Curriculum: Astrophysics |
C. Carbone
|
| Cosmological applications of gravitational waves (GW): large-scale structure effects from the cross-correlation of GW events with galaxy surveys and maps of the cosmic microwave background.
Requirements: M.sc. level knowledge of General Relativity, Cosmology and Quantum Field Theory. Basics of programming (python/c,c++/fortran) Curriculum: Astrophysics |
C. Carbone
|
| Mass diagnostics in galaxies and clusters of galaxies and dynamics of stellar systems
Curriculum: Astrophysics |
|
| Gravitational lenses.
Curriculum: Astrophysics |
|
| Cosmological probes of Dark Matter: signatures in weak gravitational lensing and galaxy clustering.
Requirements: M.sc. level knowledge of General Relativity, Cosmology and Quantum Field Theory. Basics of programming (python/c,c++/fortran) Curriculum: Astrophysics |
|
| Black hole growth.
Curriculum: Astrophysics |
|
| Protostellar disc dynamics and planet formation.
Curriculum: Astrophysics |
|
| Observations and modelling of the large-cale structure of the Universe: estimate of cosmological parameters and neutrino mass, tests of General Relativity and primordial Non-Gaussianity.
Requirements: M.sc. level knowledge of General Relativity and Cosmology. Basics of programming (python/c,c++/fortran) Curriculum: Astrophysics |
|
| LSPE/STRIP: measuring the CMB polarization from the Teide Observatory, Tenerife.
Curriculum: Astrophysics |
|
| LiteBIRD space mission for testing cosmic inflation: optical and RF characterization of the Medium-High Frequency Telescope.
Curriculum: Astrophysics |
|
| Planck space mission: detailed analysis of systematic effects in the Low Frequency Instrument.
Curriculum: Astrophysics |
|
| Molecular clouds and star-formation.
Curriculum: Astrophysics |
|
| Innovative computational techniques for future cosmic microwave background experiments.
Requirements: Basic astrophysical background, good knowledge of at least one programming language Curriculum: Astrophysics |
|
| Quantum computation over continuous-variable systems.
Curriculum: Condensed matter physic |
|
| Non- Equilibrium fluctuations in complex fluids (TechNES ESA space project).
Curriculum: Condensed matter physic |
|
| Development and characterization of neuromorphic systems based on nanostructured materials for nonconventional computation approaches.
Curriculum: Condensed matter physic |
|
| Quantum machine learning.
Curriculum: Condensed matter physic |
|
| Investigation of systems and interfaces at the nanoscale by Scanning Probe Microscopy.
Curriculum: Condensed matter physic |
|
| Investigation of biomechanics in cellular and biomolecular systems by Scanning Probe Microscopy.
Curriculum: Condensed matter physic |
|
| Theory of quantum measurements and quantum metrology.
Curriculum: Condensed matter physic |
|
| Quantum theory of superconductivity in high-pressure/high-temperature materials.
Requirements: Basic nowledge of quantum mechanics, many-body systems and structure of matter Curriculum: Condensed matter physic |
|
| Atomistic simulations of complex polymer materials subject to mechanical deformation under extreme conditions.
Requirements: Basic knowledge of numerical simulations, statistical physics, continuum mechanics and structure of matter Curriculum: Condensed matter physic |
|
| Wavefront diagnostics of radiation with orbital angular momentum.
Curriculum: Condensed matter physic |
|
| Open quantum systems theory.
Curriculum: Condensed matter physic |
|
| Experimental study of the electronic properties of novel family of nanostructured materials for energetic applications by means photoelectron spectroscopy.
Requirements: Basic knowledge of condensed matter physics Curriculum: Condensed matter physic |
|
| Simulation of complex systems, ultra-cold atoms and strongly correlated quantum systems.
Curriculum: Condensed matter physic |
|
| Applications of Computational Intelligence and Machine Learning techniques in Physics.
Curriculum: Condensed matter physic |
|
| Ultrafast photocathodes with minimum thermal emittance for the next generation coherent X-Ray sources.
Curriculum: Condensed matter physic |
D. Sertore (INFN)
C. Pagani (INFN)
|
| Efficient simulation of quantum systems and open quantum systems.
Curriculum: Condensed matter physic |
|
| Routing in quantum computers by artificial intelligence methods.
Requirements: Linear algebra Curriculum: Condensed matter physic |
|
| Quantum machine learning algorithms for the simulation of solid state systems.
Requirements: Linear algebra Curriculum: Condensed matter physic |
|
| Quantum neural networks.
Requirements: Linear algebra Curriculum: Condensed matter physic |
|
| Artificial intelligence algorithms for quantum compiling.
Requirements: Linear algebra Curriculum: Condensed matter physic |
|
| Secure quantum computing.
Requirements: Linear algebra Curriculum: Condensed matter physic |
|
| Modelling of the assembling of metallic nanoparticles into nanofilaments and nanofoams and their study of transport proprieties.
Requirements: Knowledge of Solid Physics and Surface Physics Curriculum: Condensed matter physic |
|
| Development of machine-learning potential (Gaussian regression process and neural network) for the design of nanocatalysts.
Requirements: Knowledge of Solid Physics and Surface Physics Curriculum: Condensed matter physic |
|
| Properties of positronium confined in nanocavities in condensed matter; Rydberg positronium in electric and magnetic fields.
Requirements: Basic knowledge of quantum mechanics, atomic physics and numerical methods Curriculum: Condensed matter physic |
|
| Antimatter fundamental properties: quantum decoherence with positrons, Aharonov-Bohm effect, Positronium laser cooling.
Requirements: Basic knowledge of quantum mechanics and experimental techniques Curriculum: Condensed matter physic |
M. Giammarchi (INFN)
|
| Antimatter quantum interferometry, CPT and Weak Equivalence Principle Tests.
Requirements: Basic knowledge of quantum mechanics and experimental techniques Curriculum: Condensed matter physic |
M. Giammarchi (INFN)
|
| Equilibrium and non-equilibrium fluctuations during sedimentation in normal and micro-gravity conditions.
Curriculum: Condensed matter physic |
|
| Hydrodynamics and rheology of soft materials and complex fluids.
Curriculum: Condensed matter physic |
|
| Theoretical and computational study of electron core-level spectroscopies and phenomena induced by the excitation.
Requirements: Knowledge of quantum mechanics; further basic knowledge of the Many Body theory. Curriculum: Condensed matter physic |
|
| Theoretical study and first-principles investigation of Structural, electronic, optical, and magnetic properties of nanostructures and low-dimensional systems.
Requirements: Knowledge of quantum mechanics; further basic knowledge of the Many Body theory. Curriculum: Condensed matter physic |
|
| Research on electronic and magnetic properties at equilibrium and out of equilibrium in ultrathin films and nanostructures solids. The research will include the synthesis and nanofabrication of samples with in-situ epitaxy (MBE, PLD, PVD) and time resolved spectroscopy at the 50-150fs scale by optical and photoelectric methods, spin-polarimetry, and 4-wave-mixing. The sources and experimental stations are those of the infrastructure https://www.trieste.nffa.eu/
Requirements: Condensed matter physics/structure of matter/ Quantum Physics Curriculum: Condensed matter physic |
|
| Research on surface magnetic structure with nanometric spatial resolution by measuring the spin-polarization od secondary electrons in scanning electron microscopy (SEMPA) and field-emission from scanning probe (STM, SFEMPA). Study on the magnetic configurations of nanostructures as grown and characterized in-situ and methodological developments of magnetic microscopy in the new laboratory at LASA and in combination with the fine analysis resources of the NFFA infrastructure https://www.trieste.nffa.eu/
Requirements: Condensed matter physics/structure of matter/ Quantum Physics Curriculum: Condensed matter physic |
|
| Biophysics and use of models from statistical mechanics, physics of complex systems, computational physics and machine learning to the study of biopolymers (proteins, DNA, RNA and chromosomes).
Requirements: Basic knowledge of statistical mechanics and numerical calculations. Curriculum: Condensed matter physic |
|
| Yielding and recovery in soft materials: opto-rheological and microstructural characterization.
Curriculum: Condensed matter physic |
|
| Soft-matter and biological physics with applications in quantitative biology.
Requirements: Statistical physics background, interdisciplnary interest Curriculum: Condensed matter physic |
|
| Nanoparticles (metal, semiconductor, insulator) for increasing the efficiency of thin film solar cells, in combination with for example 2D materials.
Curriculum: Condensed matter physic |
|
| Investigating hydrogen storage in metal (e.g. Magnesium) nanoparticles with optical techniques.
Curriculum: Condensed matter physic |
|
| Quantum control for quantum technologies.
Curriculum: Condensed matter physic |
|
| Quantum walks and quantum simulators.
Curriculum: Condensed matter physic |
|
| Open quantum systems and quantum technologies.
Curriculum: Condensed matter physic |
|
| Development and application of optical instrumentation.
Requirements: Basic knowledge of optics Curriculum: Condensed matter physic |
|
| Development of advanced wavefront diagnostics.
Requirements: Basic knowledge of optics Curriculum: Condensed matter physic |
|
| Heating and transport in fusion relevant plasmas.
Curriculum: Condensed matter physic |
|
| Nonlinear plasma dynamics and antimatter confinement.
Curriculum: Condensed matter physic |
|
| Modeling friction and dissipation beyond molecular-dynamics simulations: Recent advances in the theory of phonon dissipation generated by sliding objects may allow researchers to predict dynamic friction by evaluating essentially analytic formulas with no need to simulate explicit atomistic motions.
Requirements: Basic knowledge of classical and quantum statistical mechanics, and many-body theory for condensed-matter physics. Curriculum: Condensed matter physic |
|
| Cooperative effects in the cold and ultracold atomic systems.
Curriculum: Condensed matter physic |
|
| Spontaneous formation of ordered structures in cold atom gases.
Curriculum: Condensed matter physic |
|
| Molecular Nanomagnets for quantum sensing and high-density data storage.
Curriculum: Condensed matter physic |
|
| Development of resistive switching devices based on ionic liquid interfaces for ionotronic applications.
Curriculum: Condensed matter physic |
|
| Nanostructured materials with potential for energy production, conversion and storage applications: synthesis and characterization.
Curriculum: Condensed matter physic |
|
| Synchrotron radiation and free electron laser studies on clusters and nanoparticles: physico-chemical characterization; interaction with photons and energy relaxation processes in isolated nano-objects.
Curriculum: Condensed matter physic |
|
| Atomistic simulations of structural and dynamical properties of nanoscale systems: friction and dissipative phenomena.
Requirements: Basic knowledge of classical and statistical mechanics, and condensed-matter physics. Curriculum: Condensed matter physic |
|
| Theoretical and computational study of quantum transport in 1D and 2D systems with applications in electronics, spintronics and quantum technology.
Requirements: Knowledge of Solid Physics and Surface Physics Curriculum: Condensed matter physic |
|
| Generation of two-photon entangled states in polarization and / or angular momentum for applications in quantum communication and quantum key distribution.
Requirements: Knowledge of theoretical and / or experimental quantum optics and quantum information Curriculum: Condensed matter physic |
|
| Development of a pulsed laser system with high finesse cavity for X-ray generation via Compton backscattering.
Requirements: Experience of the experimental techniques of a laser laboratory Curriculum: Condensed matter physic |
|
| Modeling and development of an optical-quantum system for drone-based quantum key distribution and communication.
Requirements: Knowledge of theoretical and / or experimental quantum optics and quantum information Curriculum: Condensed matter physic |
|
| Computational and statistical mechanics approaches to biophysical phenomena.
Curriculum: Condensed matter physic |
|
| Materials property prediction and design by artificial intelligence algorithms.
Curriculum: Condensed matter physic |
|
| Phase transitions in solutions of nanoparticles made of DNA.
Curriculum: Condensed matter physic |
|
| Free-Electron Laser bases on two fold acceleration and arc compressor.
Curriculum: Condensed matter physic |
|
| Innovative tracking trigger systems for the high-luminosity frontier particle physics experiments.
Curriculum: Nuclear and particle physics |
C. Meroni (INFN)
|
| Research and development of semiconductor detectors with high space and time resolution for experiments at future accelerators and multidisciplinary applications.
Curriculum: Nuclear and particle physics |
|
| Measurements of Standard Model processes and of Higgs boson properties in proton-proton collision with the ATLAS experiment at the LHC.
Curriculum: Nuclear and particle physics |
T. Lari (INFN)
L. Perini
S. Resconi (INFN)
R. Turra (INFN)
|
| Study of physics processes at future high-energy e+e- colliders.
Curriculum: Nuclear and particle physics |
|
| Studies of properties of nuclei far from stability of interest for nucleosynthesis processes occurring in stars. Activity based on stable and radioactive beams (at CERN-ISOLDE, LNL, ILL, GSI/FAIR, RIKEN and RNPC-Osaka), employing large arrays, advanced gamma spectroscopy methods with developments of new techniques.
Requirements: Nuclear Physics. Gamma and particle detectors Curriculum: Nuclear and particle physics |
|
| Study of the gamma decay from nuclear highly collective states and study of the detectors and technique for the measurement of high energy gamma rays (5-30 MeV).
Requirements: Nuclear Physics. Gamma and particle detectors Curriculum: Nuclear and particle physics |
|
| Measurement of cross sections of nuclear reactions of astrophysical interest (Primordial nucleosynthesis, Hydrogen, Helium and Carbon burning) in the Gran Sasso underground Laboratory (LUNA and LUNA MV experiments).
Requirements: Principles of Nuclear Physics. Particle detectors Curriculum: Nuclear and particle physics |
|
| Neutrino physics and neutrino detector development with the JUNO experiment.
Curriculum: Nuclear and particle physics |
B. Caccianiga (INFN)
M. Giammarchi (INFN)
F. Ferraro
|
| Novel Monte Carlo approaches for the study of nuclear correlations.
Curriculum: Nuclear and particle physics |
E. Vigezzi (INFN)
|
| Ab initio many-body theories for investigating nuclear interaction and nucleonic star matter.
Curriculum: Nuclear and particle physics |
E. Vigezzi (INFN)
|
| Design and development of superconducting RF resonators for the future very large lepton colliders.
Curriculum: Nuclear and particle physics |
C. Pagani (INFN)
L. Monaco (INFN)
|
| Search of Time modulation from low-mass Dark Matter using twin detectors based on high purity NaI crystal matrices located in both hemispheres: Gran Sasso and Australia.
Curriculum: Nuclear and particle physics |
|
| Development of cryogenic light detectors based on SiPM matrices for applications in the field of Neutrino Physics and Dark Matter.
Curriculum: Nuclear and particle physics |
M. Citterio (INFN)
P. Sala (INFN)
|
| Direct nuclear reactions to probe structure at the limits of stability.
Curriculum: Nuclear and particle physics |
E. Vigezzi (INFN)
|
| Study of atomic nuclei using direct and inverse Density Functional Theory.
Curriculum: Nuclear and particle physics |
E. Vigezzi (INFN)
|
| Searches for new physics in proton-proton collisions with the ATLAS experiment at the LHC.
Curriculum: Nuclear and particle physics |
T. Lari INFN
L. Perini
S. Resconi (INFN)
R. Turra (INFN)
|
| Ultra High Energy Cosmic Rays with the Auger Observatory.
Curriculum: Nuclear and particle physics |
L. Caccianiga (INFN)
|
| Investigation by analytical and numerical methods and experimental characterization of high field superconducting magnets, 15 tesla) for the post-LHC future colliders.
Curriculum: Nuclear and particle physics |
M. Statera (INFN)
|
| Study and small scale experimental models of magnets wound with HTS (High Temperature Superconductors) for the MUON COLLIDER project.
Curriculum: Nuclear and particle physics |
M. Statera (INFN)
|
| New technology development, based on HTS (High Temperature Superconductor), for 10-20 tesla high field magnets and space magnets for next generation particle and astro-particle experiments.
Curriculum: Nuclear and particle physics |
M. Statera (INFN)
|
| Development of ASICs and advanced electronics systems for particle physics.
Curriculum: Nuclear and particle physics |
M. Citterio (INFN)
|
| Measurements of electromagnetic dipole moments of short-lived baryons at LHC.
Curriculum: Nuclear and particle physics |
|
| Flavour physics and CP violation in the LHCb experiment.
Curriculum: Nuclear and particle physics |
P. Gandini (INFN)
|
| Experimental Nuclear Physics for medicine: development of detectors and cross section measurements useful for hadrotherapy.
Curriculum: Nuclear and particle physics |
S. Muraro (INFN)
|
| Cryogenic front-end electronics characterization by innovative digital signal processing techniques within the LEGEND Collaboration (INFN Gran Sasso).
Curriculum: Nuclear and particle physics |
|
| Equation of state of nucleonic matter, applications to compact objects and multi-messenger signals.
Curriculum: Nuclear and particle physics |
E. Vigezzi (INFN)
|
| AdS/CFT correspondence and supersymmetric field theories.
Curriculum: Theoretical physics |
A. Santambrogio (INFN)
|
| Foundations of quantum mechanics.
Curriculum: Theoretical physics |
|
| Black holes in supergravity and string theory.
Curriculum: Theoretical physics |
|
| Inflation and string theory.
Curriculum: Theoretical physics |
|
| Statistical mechanics, out-of-equilibrium systems, complex systems, with interdisciplinary applications in quantitative biology.
Requirements: Basic knowledge of statistical mechanics, interdisciplinary interest Curriculum: Theoretical physics |
|
| Statistical physics of deep learning; the role of data structure concerning expressivity and generalization in machine learning; models of neural networks as complex systems.
Requirements: Basic knowledge of statistical mechanics and machine learning; interest in interdisciplinary applications of theoretical physics. Curriculum: Theoretical physics |
|
| Mathematical and statistical computational models for AI development in healthcare applications.
Curriculum: Theoretical physics |
|
| Quantum simulation on classical hardware, quantum computing techniques and quantum ML applied to High Energy Physics.
Curriculum: 4. Theoretical physics |
|
| Computational models with hardware accelerators for High Energy Physics applications.
Curriculum: 4. Theoretical physics |
|
| Theoretical physics at the LHC: fundamental interactions and the Higgs boson in the standard model and beyond.
Curriculum: Theoretical physics |
|
| Parton Distribution Functions: machine learning, software tools, perturbative QCD.
Curriculum: Theoretical physics |
|
| Development of bio-hybrid actuators for biomedical applications.
Requirements: Basic notions in microfabrication and polymer chemistry Curriculum: Applied physics |
|
| Light, X-ray and neutron scattering by nano-structures (amyloid peptides and proteins, biocolloids) in solution and in interaction with biological membranes.
Curriculum: Applied physics |
|
| Electron Microscopy (EM), in scanning mode (SEM), in transmission mode (TEM), and in scanning and transmission mode (STEM) and its related, compositional spectroscopies (EDS and EELS) for the advanced characterization of materials, even 3D, and upon external biasing or heating stimulus (in situ EM).
Curriculum: Applied physics |
|
| Statistical properties of the surfaces of glaciers.
Curriculum: Applied physics |
|
| Development and application of computational methods to study the structure and dynamics of biomolecules.
Requirements: Biophysics/Statistical Mechanics Curriculum: Applied physics |
|
| Superconducting accelerating cavities with minimum cryogenic losses for intense sources of neutrinos and spallation neutrons for spectroscopy and transmutation.
Curriculum: Applied physics |
C. Pagani (INFN)
A. Bosotti (INFN)
R. Paparella (INFN)
|
| Laser source proton accelerators for therapeutic beams.
Curriculum: Applied physics |
D. Giove (INFN)
C. Pagani (INFN)
|
| Laser based injector for high brightness electron beams.
Curriculum: Applied physics |
D. Giove (INFN)
L. Serafini (INFN)
D. Sertore (INFN)
C. Pagani (INFN)
|
| Biomimetic scaffolds for tissue-engineered tissue replacement: structural properties by spectroscopic, calorimetric and mechanical studies.
Curriculum: Applied physics |
|
| Structural signature of dynamical arrest in epithelial cell tissues.
Curriculum: Applied physics |
|
| Production optimization with unconventional techniques and at high specific activity of radionuclides for applications in medicine (radiodiagnostic, metabolic radiotherapy towards the theranostic), environmental and nanotoxicological studies.
Requirements: Basic knowledge of Health Physics and Radioprotection Curriculum: Applied physics |
|
| Ultrasensitive optical biosensors based on interferometric reflective imaging for digital detection of single viruses.
Curriculum: Applied physics |
|
| Design and characterization of antifreeze materials.
Curriculum: Applied physics |
|
| Internal dosimetry in nuclear medicine.
Curriculum: Applied physics |
|
| Development and characterization of novel materials and methodologies for ionizing radiation detection and dosimetry.
Curriculum: Applied physics |
S. Gallo
|
| Development of new superconducting dipole magnet technology (multifunction, curved, fast ramped) for the EU program (H2020-HITRI/IFAST for next generation hadron therapy.
Curriculum: Applied physics |
M. Statera (INFN)
|
| Multivalent cooperative binding for high sensitive molecular recognition by optical biosensor.
Curriculum: Applied physics |
|
| Understanding membraneless organelles: phase behaviour and molecular interactions in protein-nucleic acids coacervates.
Curriculum: Applied physics |
|
| Climate and its variability and change in Italy, the Alpine Region and the Mediterranean area.
Curriculum: Applied physics |
|
| Statistical methods in UV-VIS-NIR reflectance spectroscopy of pigments and dyes in paintings.
Curriculum: Applied physics |
|
| Magnetic nanoparticles: fundamental properties and applications to biomedicine.
Curriculum: Applied physics |
|
| Hydrogels and biological interfaces for applications in nanomedicine.
Curriculum: 5. Applied physics |
|
| Nanocomposite systems for soft robotics.
Curriculum: Applied physics |
|
| Development of experimental and modelling advanced approaches for the study of atmospheric aerosol properties and sources.
Curriculum: Applied physics |
|
| Development of Monte Carlo methods for the calculation of interaction of Radiation with Matter, focusing in particular on biomedical applications.
Curriculum: Applied physics |
S. Muraro (INFN)
|
| Can a fluid be polar? Understanding the newly discovered ferroelectric liquid crystal phase.
Curriculum: Applied physics |
|
| Physics and application of Inverse Compton Sources.
Curriculum: Applied physics |
|
| Development of advanced experimental techniques and of experimental models for the investigation of interactions at cell surface.
Curriculum: Applied physics |
|
| Extracellular vesicles: structural characterisation by neutron and X-ray techniques and study of their internalisation mechanisms.
Curriculum: Applied physics |
|
| Quantum Communication for Power Systems (Ex DM 352/2022)
Curriculum: Condensed matter physic |
|
| Characterisation and assessment of traffic non exhaust PM (Ex DM 352/2022)
Curriculum: Applied physics |
|
| Efficient classical simulation of near-term quantum computers with tensor networks, with applications to quantum chemistry simulations (Ex DM 352/2022)
Curriculum: Condensed matter physic |
Courses list
February 2023
| Courses or activities | Professor(s) | ECTS | Total hours | Language |
|---|---|---|---|---|
| Optional | ||||
| Advanced Topics in Astrophysics and Plasma Physics-Fundamentals of Cosmic Structure Formation | 2 | 10 | Italian, English | |
March 2023
| Courses or activities | Professor(s) | ECTS | Total hours | Language |
|---|---|---|---|---|
| Optional | ||||
| Advanced Topics in Astrophysics and Plasma Physics-Bayesian Statistics in Astronomy | 2 | 10 | Italian, English | |
| Advanced Topics in Astrophysics and Plasma Physics-Cosmology | 2 | 10 | Italian, English | |
| Advanced Topics in Astrophysics and Plasma Physics-Observations of the Cosmic Microwave Background | 2 | 10 | Italian, English | |
April 2023
| Courses or activities | Professor(s) | ECTS | Total hours | Language |
|---|---|---|---|---|
| Optional | ||||
| Advanced Topics in Astrophysics and Plasma Physics-Collective Phenomena in Plasma Physics | 2 | 10 | Italian, English | |
June 2023
| Courses or activities | Professor(s) | ECTS | Total hours | Language |
|---|---|---|---|---|
| Optional | ||||
| Advanced Topics in Astrophysics and Plasma Physics-Fundamentals of Computational Fluid Dynamics in Astrophysics | 2 | 10 | Italian, English | |
March 2023
| Courses or activities | Professor(s) | ECTS | Total hours | Language |
|---|---|---|---|---|
| Optional | ||||
| Quantum Theory of Matter | 6 | 30 | English | |
June 2023
| Courses or activities | Professor(s) | ECTS | Total hours | Language |
|---|---|---|---|---|
| Optional | ||||
| Quantum Coherent Phenomena | 6 | 30 | Italian, English | |
March 2023
| Courses or activities | Professor(s) | ECTS | Total hours | Language |
|---|---|---|---|---|
| Optional | ||||
| Nuclear Structure and Reaction Dynamics with Radioactive Beams | 4 | 24 | Italian, English | |
| Nuclear Structure Studied with Stable and Radioactive Beams | 2 | 10 | Italian, English | |
| Nuclear Structure Theory: Density Functional Methods in Nuclear Physics | 2 | 10 | Italian, English | |
May 2023
| Courses or activities | Professor(s) | ECTS | Total hours | Language |
|---|---|---|---|---|
| Optional | ||||
| Neutrino Physics | 2 | 10 | English | |
September 2023
| Courses or activities | Professor(s) | ECTS | Total hours | Language |
|---|---|---|---|---|
| Optional | ||||
| Advanced Topics in Particle Physics | 4 | 20 | English | |
January 2023
| Courses or activities | Professor(s) | ECTS | Total hours | Language |
|---|---|---|---|---|
| Optional | ||||
| Computational, Simulation and Machine Learning Methods in High Energy Physics and Beyond: Machine Learning | 3 | 15 | English | |
| Computational, Simulation and Machine Learning Methods in High Energy Physics and Beyond: Monte Carlo Methods. | 3 | 15 | English | |
February 2023
| Courses or activities | Professor(s) | ECTS | Total hours | Language |
|---|---|---|---|---|
| Optional | ||||
| 4d and 3d Theories with Four Supercharges: Field Theory, D-Branes, Holography and Localization. | 7 | 35 | Italian, English | |
June 2023
| Courses or activities | Professor(s) | ECTS | Total hours | Language |
|---|---|---|---|---|
| Optional | ||||
| Computational, Simulation and Machine Learning Methods in High Energy Physics and Beyond: Automated Computational Tools. | 3 | 15 | English | |
December 2022
| Courses or activities | Professor(s) | ECTS | Total hours | Language |
|---|---|---|---|---|
| Optional | ||||
| Instruments and Methods for a Cultural Understanding of Physics | 6 | 30 | Italian, English | |
May 2023
| Courses or activities | Professor(s) | ECTS | Total hours | Language |
|---|---|---|---|---|
| Optional | ||||
| Experimental Methods for the Investigation of Systems At the Nanoscale | 6 | 30 | English | |
Following the programme of study
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