PHYSICS
- Anno accademico
- 2022/2023 Programmi anni precedenti
- Titolo corso in inglese
- PHYSICS
- Codice insegnamento
- FOY14 (AF:431863 AR:236369)
- Lingua di insegnamento
- Inglese
- Modalità
- Online
- Crediti formativi universitari
- 6
- Livello laurea
- Corso di Formazione (DM270)
- Settore scientifico disciplinare
- NN
- Periodo
- II Semestre
- Anno corso
- 1
- Sede
- VENEZIA
- Spazio Moodle
- Link allo spazio del corso
Inquadramento dell'insegnamento nel percorso del corso di studio
Il corso di Fisica (FOY14) del Foundation Year ha lo scopo di introdurre concetti fondamentali come il moto rettilineo uniforme, le leggi di Newton sul moto oltre che ai concetti di Lavoro ed Energia; il corso darà i fondamenti per sviluppare capacità di pensiero critico e risoluzione dei problemi.
Risultati di apprendimento attesi
Gli studenti sono invitati a partecipare attivamente alle lezioni, completare le esercitazioni e a fare domande durante le lezioni. Durante il corso verranno sviluppate le competenze al problem-solving applicando concetti matematici alla risoluzione di problemi di fisica.
Prerequisiti
Conoscenza base di matematica delle Scuole Superiori
Contenuti
Lecture 1 - The Nature of Science and Physics (2h)
• Introduction to Science and the Realm of Physics, Physical Quantities, and Units
• Physical Quantities and Units
• Accuracy, Precision, and Significant Figures
• Approximation
Lecture 2 - Kinematics of a point: rectilinear motion (2h)
• Introduction to One-Dimensional Kinematics
• Rectilinear motion
• Velocity in the rectilinear motion
• Acceleration in rectilinear motion
• Vertical motion of a body
• Simple harmonic motion
• Rectilinear exponential motion break
• Velocity and acceleration as a function of body position
Lecture 3 - Kinematics of a point: motion on a plane (4h)
• Motion on a plane. Position and speed
• Acceleration of the motion on a plane
• Circular motion
• Parabolic motion of bodies
• Motion in space
• Summary
Lecture 4 - Dynamics of a point: Newton's Laws of Motion (4h)
• Inertia Principle. Introduction to the Force Concept
• Newton’s Law of Motion
• Momentum and impulse concepts
• Resultant of forces. Equilibrium. Constraint reactions
• Forces classification
• Dynamical action of forces
• Weight
• Friction force
• Inclined plane
• Elastic force
• Viscous friction force
• Centripetal force
• Simple pendulum
Lecture 5 - Dynamics of the point: Work, Energy, and Energy Resources (4h)
• Work, power, and kinetic energy
• Work of the Weight force
• Work of the elastic force
• Work of the friction force
• Conservative Forces and Potential Energy
• Conservation of the mechanic energy
• Angular momentum and force momentum
Lecture 6 - Relative Motions (2h)
• Reference systems, velocity, and relative accelerations
• Inertial reference systems
• Galilean relativity
Lecture 7 - Dynamics of complex systems (4h)
• Complex systems of points. Internal and external forces
• Center of mass
• Conservation of Momentum
• Angular momentum conservation theorem
• Center of mass reference system
• König’s theorems
• Kinetic energy theorem
Lecture 8 - Mechanical properties of fluids (4h)
• Introduction
• Pressure
• Static equilibrium of a fluid
• Archimedes’ principle
• Internal Friction. Viscosity. Ideal fluid.
• Motion of a fluid. Stationary regime. Flow rate.
• Bernoulli theorem
• Laminar motion
Lecture 9 - Rotational Motion and Angular Momentum (4h)
• Introduction to Rotational Motion and Angular Momentum
• Angular Acceleration
• Kinematics of Rotational Motion
• Dynamics of Rotational Motion: Rotational Inertia
• Rotational Kinetic Energy: Work and Energy Revisited
• Angular Momentum and Its Conservation
• Collisions of Extended Bodies in Two Dimensions
Lecture 10 - Fluid Statics (4h)
• Introduction to Fluid Statics
• What Is a Fluid?
• Density
• Pressure
• Variation of Pressure with Depth in a Fluid
• Pascal’s Principle
• Gauge Pressure, Absolute Pressure, and Pressure Measurement
• Archimedes’ Principle
• Cohesion and Adhesion in Liquids: Surface Tension and Capillary Action
Lecture 11 - Temperature, Kinetic Theory, and the Gas Laws (4h)
• Thermodynamics systems and states
• Thermodynamic equilibrium
• Temperature
• Adiabatic systems. Joule experiments. Heat.
• First principle of Thermodynamics
• Thermodynamics transformations. Work and Heat.
• Calorimetry
• The Ideal Gas Law
• Phase Changes
• Humidity, Evaporation, and Boiling
• Introduction to Science and the Realm of Physics, Physical Quantities, and Units
• Physical Quantities and Units
• Accuracy, Precision, and Significant Figures
• Approximation
Lecture 2 - Kinematics of a point: rectilinear motion (2h)
• Introduction to One-Dimensional Kinematics
• Rectilinear motion
• Velocity in the rectilinear motion
• Acceleration in rectilinear motion
• Vertical motion of a body
• Simple harmonic motion
• Rectilinear exponential motion break
• Velocity and acceleration as a function of body position
Lecture 3 - Kinematics of a point: motion on a plane (4h)
• Motion on a plane. Position and speed
• Acceleration of the motion on a plane
• Circular motion
• Parabolic motion of bodies
• Motion in space
• Summary
Lecture 4 - Dynamics of a point: Newton's Laws of Motion (4h)
• Inertia Principle. Introduction to the Force Concept
• Newton’s Law of Motion
• Momentum and impulse concepts
• Resultant of forces. Equilibrium. Constraint reactions
• Forces classification
• Dynamical action of forces
• Weight
• Friction force
• Inclined plane
• Elastic force
• Viscous friction force
• Centripetal force
• Simple pendulum
Lecture 5 - Dynamics of the point: Work, Energy, and Energy Resources (4h)
• Work, power, and kinetic energy
• Work of the Weight force
• Work of the elastic force
• Work of the friction force
• Conservative Forces and Potential Energy
• Conservation of the mechanic energy
• Angular momentum and force momentum
Lecture 6 - Relative Motions (2h)
• Reference systems, velocity, and relative accelerations
• Inertial reference systems
• Galilean relativity
Lecture 7 - Dynamics of complex systems (4h)
• Complex systems of points. Internal and external forces
• Center of mass
• Conservation of Momentum
• Angular momentum conservation theorem
• Center of mass reference system
• König’s theorems
• Kinetic energy theorem
Lecture 8 - Mechanical properties of fluids (4h)
• Introduction
• Pressure
• Static equilibrium of a fluid
• Archimedes’ principle
• Internal Friction. Viscosity. Ideal fluid.
• Motion of a fluid. Stationary regime. Flow rate.
• Bernoulli theorem
• Laminar motion
Lecture 9 - Rotational Motion and Angular Momentum (4h)
• Introduction to Rotational Motion and Angular Momentum
• Angular Acceleration
• Kinematics of Rotational Motion
• Dynamics of Rotational Motion: Rotational Inertia
• Rotational Kinetic Energy: Work and Energy Revisited
• Angular Momentum and Its Conservation
• Collisions of Extended Bodies in Two Dimensions
Lecture 10 - Fluid Statics (4h)
• Introduction to Fluid Statics
• What Is a Fluid?
• Density
• Pressure
• Variation of Pressure with Depth in a Fluid
• Pascal’s Principle
• Gauge Pressure, Absolute Pressure, and Pressure Measurement
• Archimedes’ Principle
• Cohesion and Adhesion in Liquids: Surface Tension and Capillary Action
Lecture 11 - Temperature, Kinetic Theory, and the Gas Laws (4h)
• Thermodynamics systems and states
• Thermodynamic equilibrium
• Temperature
• Adiabatic systems. Joule experiments. Heat.
• First principle of Thermodynamics
• Thermodynamics transformations. Work and Heat.
• Calorimetry
• The Ideal Gas Law
• Phase Changes
• Humidity, Evaporation, and Boiling
Testi di riferimento
a) Free Physics Book from OpenStax (source: RICE University)
b) PDF or PPT notes
c) Elementi di Fisica (Authors: Mazzo, Nigro, Voci)
b) PDF or PPT notes
c) Elementi di Fisica (Authors: Mazzo, Nigro, Voci)
Modalità di verifica dell'apprendimento
Il voto finale è basato sulla somma della valutazione mid-term e finale.
Il voto finale è calcolato nel seguente modo:
a) Partecipazione alle lezioni – 20%
b) Esame Mid-term – 30%
c) Esame Finale – 50%
L'esame di mid-term è scritto.
L'esame finale sarà scritto e opzionalmente con una parte orale.
Il voto finale è calcolato nel seguente modo:
a) Partecipazione alle lezioni – 20%
b) Esame Mid-term – 30%
c) Esame Finale – 50%
L'esame di mid-term è scritto.
L'esame finale sarà scritto e opzionalmente con una parte orale.
Modalità di esame
scritto e orale
Metodi didattici
- Power point presentations
- Esercizi alla lavagna
- Esercizi alla lavagna
Programma definitivo.
Data ultima modifica programma: 22/02/2023