Università degli Studi di Napoli "Parthenope"

Teaching schedule

Academic year: 
2017/2018
Belonging course: 
Course of Master's Degree Programme on NAVIGATION SCIENCE AND TECHNOLOGIES
Disciplinary sector: 
ASTRONOMY AND ASTROPHYSICS (FIS/05)
Credits: 
9
Year of study: 
1
Teachers: 
Cycle: 
Second semester
Hours of front activity: 
72

Language

Italian (most of bibliograhy in English)

Course description

We aim to present to the student an introduction to space science, focused on Solar System structure and evolution, and to space technologies used in space activities, in particular system engineering of a spacecraft.
Knowledge and understanding: The student must demonstrate knowledge and understanding of the fundamentals of Solar System science (physics, geophysics, geology) and the physical laws and technologies on which a space project is based upon.
Ability to apply knowledge and understanding: Students must demonstrate to use their own acquired knowledge to discuss and explain the main physical processes acting in the Solar System, limits and capabilities of space technology.
Independent judgment: The student must be able to evaluate from his/her point of view physical problems different from what was discussed during the lessons.
Communication Skills: The student shall be able to support a conversation on the topics covered during the unit, with proper scientific language and by correctly using mathematics and plots.
Learning Skills: The student must be able to update and deepen autonomously specific topics and applications related to studied topics.

Prerequisites

The student must know mathematical analysis and classical physics, including kinematics, point and rigid body dynamics electro-magnetism.

Syllabus

CONTENTS (and detailed bibliography)
 Gravitation and Kepler’s laws (RD2 cap V.1-V.5)
 Introduction to Solar System (RD1 c1; slides )
 Black body radiation, spectrum and emittance, Stefan-Boltzmann’s and Wien’s laws, Sun spectrum, Earth atmosphere transmission (RD2 cap XIV.4; slides )
 Thermal equilibrium in the Solar System; Planets thermal balance (RD3 TopicX)
 Electromagnetic radiation quantization, Bohr’s atom, angular momentum quantization, energy quantization (RD2-II capXII.6)
 Photons emission and absorption; introduction to atomic and molecular spectroscopy, solids and gases spectra, vibrational and rot-vibrational transitions; reflection spectroscopy (slides )
 Methods of studying the Solar System (RD1 c3.1)
 Solar System in the galaxy, cosmic distance scale, universe evolution, star evolution, nucleosynthesis (RD1 c2)
 Solar System formation, Sun evolution, other planetary systems (RD1 c4; Pres. )
 Terrestrial planets formation (Mercury, Venus, Earth, Moon) (RD1 c6)
 Minor body classification and dynamics; TNO, KBO (RD1 c12; Slides )
 Comets (RD1 c11; Slides )
 Mars exploration (2 presentazioni )
 Planetary geology (Slides )
 Comets and Rosetta mission (Slides )
 Asteroids, NEOs (RD1 c7; Slides )
 Origin and evolution of interplanetary dust, meteors, local and global effects of the Eart – extraterrestrial bodies interaction, meteoroids, asteroids impact and consequances on climate, Torino scale, http://neo.jpl.nasa.gov/orbits/ , http://neo.jpl.nasa.gov/ca/ http://neo.jpl.nasa.gov/risk/ , http://spaceguard.esa.int/tumblingstone/issues/num11/it/main.htm (RD1, c13; Slides )
 Eddington accretion (RD3 TopicAL page440)
 Heating by accretion (RD3 TopicAE page 411)
 Sphere of influence (RD3 TopicAA.4 page 383)
 Tide and recession of the Moon (RD3 TopicY page 383)
 Poynting-Robertson Effect (RD3 TopicAG page 424)
 Planetary magnetism (RD3 TopicV page 345)
 Magnetic interaction between planets and stars (RD3 TopicW page 364)
 Introduction to space systems engineering (RD4 c1)
 Space environment and consequence on mission design (RD4 c2)
 Translation and rotation dynamics, propulsion dynamics, inertia tensor, precession and nutation, S/C configuration (w and w/o spin) (RD4 c3)
 Fundamentals of orbital motion, perturbations (RD4 c4)
 Mission planning, influence sphere, fly-by and gravitation assist (RD4 c5)
 Propulsion (RD4 c6)
 Launchers (RD4 c7)
 Synthetic aperture radar (Slides )
 Attitude control system (RD4 c9)
 Digital photo-camera for space applications (Slides )
 Spacecraft system engineering (RD4 c19)

CONTENTS (and detailed bibliography)
 Gravitation and Kepler’s laws (RD2 cap V.1-V.5)
 Introduction to Solar System (RD1 c1; slides )
 Black body radiation, spectrum and emittance, Stefan-Boltzmann’s and Wien’s laws, Sun spectrum, Earth atmosphere transmission (RD2 cap XIV.4; slides )
 Thermal equilibrium in the Solar System; Planets thermal balance (RD3 TopicX)
 Electromagnetic radiation quantization, Bohr’s atom, angular momentum quantization, energy quantization (RD2-II capXII.6)
 Photons emission and absorption; introduction to atomic and molecular spectroscopy, solids and gases spectra, vibrational and rot-vibrational transitions; reflection spectroscopy (slides )
 Methods of studying the Solar System (RD1 c3.1)
 Solar System in the galaxy, cosmic distance scale, universe evolution, star evolution, nucleosynthesis (RD1 c2)
 Solar System formation, Sun evolution, other planetary systems (RD1 c4; Pres. )
 Terrestrial planets formation (Mercury, Venus, Earth, Moon) (RD1 c6)
 Minor body classification and dynamics; TNO, KBO (RD1 c12; Slides )
 Comets (RD1 c11; Slides )
 Mars exploration (2 presentazioni )
 Planetary geology (Slides )
 Comets and Rosetta mission (Slides )
 Asteroids, NEOs (RD1 c7; Slides )
 Origin and evolution of interplanetary dust, meteors, local and global effects of the Eart – extraterrestrial bodies interaction, meteoroids, asteroids impact and consequances on climate, Torino scale, http://neo.jpl.nasa.gov/orbits/ , http://neo.jpl.nasa.gov/ca/ http://neo.jpl.nasa.gov/risk/ , http://spaceguard.esa.int/tumblingstone/issues/num11/it/main.htm (RD1, c13; Slides )
 Eddington accretion (RD3 TopicAL page440)
 Heating by accretion (RD3 TopicAE page 411)
 Sphere of influence (RD3 TopicAA.4 page 383)
 Tide and recession of the Moon (RD3 TopicY page 383)
 Poynting-Robertson Effect (RD3 TopicAG page 424)
 Planetary magnetism (RD3 TopicV page 345)
 Magnetic interaction between planets and stars (RD3 TopicW page 364)
 Introduction to space systems engineering (RD4 c1)
 Space environment and consequence on mission design (RD4 c2)
 Translation and rotation dynamics, propulsion dynamics, inertia tensor, precession and nutation, S/C configuration (w and w/o spin) (RD4 c3)
 Fundamentals of orbital motion, perturbations (RD4 c4)
 Mission planning, influence sphere, fly-by and gravitation assist (RD4 c5)
 Propulsion (RD4 c6)
 Launchers (RD4 c7)
 Synthetic aperture radar (Slides )
 Attitude control system (RD4 c9)
 Digital photo-camera for space applications (Slides )
 Spacecraft system engineering (RD4 c19)

Teaching Methods

72 hours of lessons supported by presentations and other multi-media material available to students

Textbooks

Bibliography (details are given for each topic).
RD1 Encrenanz et al. The Solar System Springer 3rd edition
RD2-I & II Mencuccini, Silvestrini Fisica I&II Liguori Ed.
RD3 Coole, Woolfson Planetary Science Institute of Physics Publishing
RD4 Fortescue e altri Spacecraft Systems Engineering Whiley
Slides used during the lessons are also to be considered (they are made available upon request).

Learning assessment

The purpose of the assessment is to quantify the level of achievement of the training objectives previously indicated. The verification procedure consists of an oral examination during which the ability of the student to apply the topics discussed during the course to different problems is tested.

More information