Programme

§I. Introduction: inertia and covariance

Galilean Relativity and Special Relativity. The Equivalence Principle. Motivations for general covariance. Local inertial frames.

§II. Dynamical spacetime: basics of General Relativity

Curvilinear coordinates. Vectors and tensors under general coordinate transformations. Parallel transport and Christoffel symbols. Covariant derivatives and metric compatibility. Covariantly conserved vectors and conserved vector densities. Transformation of the Christoffel symbols. Ricci's theorem. Geodesics and their Newtonian limit. Time-like, null and space-like curves. Normal coordinates and local inertial frames. Covariant derivation along curves. Riemann curvature tensor. Algebraic properties. Bianchi identities. Local inertial frames. Characterisation of flat spaces. Geodesic deviation. Einstein-Hilbert action and equations of motion. The Palatini identity. Minimal coupling to scalar fields and to Maxwell fields.

§III. Linear approximation and gravitational waves

Motivations. Weak fluctuations over flat space-time: linearised Riemann tensor and its abelian gauge invariance. Equations of motion: de Donder gauge and gravitational waves. Comparing to Maxwell's theory.

§IV. Isometries and maximally symmetric spaces

Symmetries of tensors: form-invariance. Killing equations. Integrability condition and maximal number of isometries. The Lie derivative. Killing vectors and conservation laws. The example of Minkowski space. Translational isometries.

§V. Basics of the Schwarschild solution

Schwarzschild metric. Spherical symmetry and Birkhoff's theorem (without proof). Killing vectors of Schwarzschild's metric. Gravitational redshift.

Core Documentation

-Carroll S Spacetime and Geometry: An Introduction to General Relativity (Addison-Wesley 2014/Cambridge University Press, 2019)
-Dirac P A M General Theory of Relativity (Princeton University Press, 1996)
-Hartle S Gravity: An Introduction to Einstein's General Relativity (Cambridge University Press, 2021)
-Rovelli C, General Relativity - the Essentials, (Cambridge University Press, 2021).
-Weinberg S, Gravitation and Cosmology - principles and applications of the general theory of relativity, (John Wiley \& Sons, 1972).

Type of delivery of the course

Blackboard lectures

Type of evaluation

Partials or oral exams

Programme

- Cosmological Principle And Robertson-Walker Metric
- Friedmann Equations
- The Standard Cosmological Model
- Redshift, Cosmological Distances And Cosmological Horizons
- Cosmological Parameters And Their Measurement
- Classical Cosmologial Tests: Hubble Test. Angular Diameter Test. Counts
- Cosmological Constant
- Cosmic Fluids And Their Equation Of State
- Thermal History Of The Universe: Decoupling, Recombination
- Matter-Antimatter Asymmetry
- Beyond Standard Model: Horizon And Flatness Paradoxes, Introduction To Cosmic Inflation
- Dark Matter
- Brief History Of The Universe
- Cosmological Nucleosynthesis
- Matter Dominated Era. Reionization.
- Fcosmic Microwave Background
- Jeans Theory Of Gravitational Instability
- Evolution Of Cosmic Structures
- Spectrum Of Density Perturbations. Linear And Non-Linear Evolution Of The Cosmic Density Field
- Spherical Collapse And Press & Schechter Theory
- Introduction To Numerical Approaches To Structure Formation: N-Body Simultaions
- Key Processes In Galaxy Formation
- Introduction To Open Problems In Structure Formation

Core Documentation

Coles P., Lucchin F. Cosmology [Wiley 2000]
Peebles P.J.E. 1993. Principles of Physical Cosmology [Princeton Series in Physics 1993]

Type of delivery of the course

frontal teaching lessons

Type of evaluation

The exam takes place in oral form The questions cover all the topics of the course.

Programme

§I. Introduction: inertia and covariance

Galilean Relativity and Special Relativity. The Equivalence Principle. Motivations for general covariance. Local inertial frames.

§II. Dynamical spacetime: basics of General Relativity

Curvilinear coordinates. Vectors and tensors under general coordinate transformations. Parallel transport and Christoffel symbols. Covariant derivatives and metric compatibility. Covariantly conserved vectors and conserved vector densities. Transformation of the Christoffel symbols. Ricci's theorem. Geodesics and their Newtonian limit. Time-like, null and space-like curves. Normal coordinates and local inertial frames. Covariant derivation along curves. Riemann curvature tensor. Algebraic properties. Bianchi identities. Local inertial frames. Characterisation of flat spaces. Geodesic deviation. Einstein-Hilbert action and equations of motion. The Palatini identity. Minimal coupling to scalar fields and to Maxwell fields.

§III. Linear approximation and gravitational waves

Motivations. Weak fluctuations over flat space-time: linearised Riemann tensor and its abelian gauge invariance. Equations of motion: de Donder gauge and gravitational waves. Comparing to Maxwell's theory.

§IV. Isometries and maximally symmetric spaces

Symmetries of tensors: form-invariance. Killing equations. Integrability condition and maximal number of isometries. The Lie derivative. Killing vectors and conservation laws. The example of Minkowski space. Translational isometries.

§V. Basics of the Schwarschild solution

Schwarzschild metric. Spherical symmetry and Birkhoff's theorem (without proof). Killing vectors of Schwarzschild's metric. Gravitational redshift.

Core Documentation

-Carroll S Spacetime and Geometry: An Introduction to General Relativity (Addison-Wesley 2014/Cambridge University Press, 2019)
-Dirac P A M General Theory of Relativity (Princeton University Press, 1996)
-Hartle S Gravity: An Introduction to Einstein's General Relativity (Cambridge University Press, 2021)
-Rovelli C, General Relativity - the Essentials, (Cambridge University Press, 2021).
-Weinberg S, Gravitation and Cosmology - principles and applications of the general theory of relativity, (John Wiley \& Sons, 1972).

Type of delivery of the course

Blackboard lectures

Type of evaluation

Partials or oral exams

Programme

- Cosmological Principle And Robertson-Walker Metric
- Friedmann Equations
- The Standard Cosmological Model
- Redshift, Cosmological Distances And Cosmological Horizons
- Cosmological Parameters And Their Measurement
- Classical Cosmologial Tests: Hubble Test. Angular Diameter Test. Counts
- Cosmological Constant
- Cosmic Fluids And Their Equation Of State
- Thermal History Of The Universe: Decoupling, Recombination
- Matter-Antimatter Asymmetry
- Beyond Standard Model: Horizon And Flatness Paradoxes, Introduction To Cosmic Inflation
- Dark Matter
- Brief History Of The Universe
- Cosmological Nucleosynthesis
- Matter Dominated Era. Reionization.
- Fcosmic Microwave Background
- Jeans Theory Of Gravitational Instability
- Evolution Of Cosmic Structures
- Spectrum Of Density Perturbations. Linear And Non-Linear Evolution Of The Cosmic Density Field
- Spherical Collapse And Press & Schechter Theory
- Introduction To Numerical Approaches To Structure Formation: N-Body Simultaions
- Key Processes In Galaxy Formation
- Introduction To Open Problems In Structure Formation

Core Documentation

Coles P., Lucchin F. Cosmology [Wiley 2000]
Peebles P.J.E. 1993. Principles of Physical Cosmology [Princeton Series in Physics 1993]

Type of delivery of the course

frontal teaching lessons

Type of evaluation

The exam takes place in oral form The questions cover all the topics of the course.

Programme

§I. Introduction: inertia and covariance

Galilean Relativity and Special Relativity. The Equivalence Principle. Motivations for general covariance. Local inertial frames.

§II. Dynamical spacetime: basics of General Relativity

Curvilinear coordinates. Vectors and tensors under general coordinate transformations. Parallel transport and Christoffel symbols. Covariant derivatives and metric compatibility. Covariantly conserved vectors and conserved vector densities. Transformation of the Christoffel symbols. Ricci's theorem. Geodesics and their Newtonian limit. Time-like, null and space-like curves. Normal coordinates and local inertial frames. Covariant derivation along curves. Riemann curvature tensor. Algebraic properties. Bianchi identities. Local inertial frames. Characterisation of flat spaces. Geodesic deviation. Einstein-Hilbert action and equations of motion. The Palatini identity. Minimal coupling to scalar fields and to Maxwell fields.

§III. Linear approximation and gravitational waves

Motivations. Weak fluctuations over flat space-time: linearised Riemann tensor and its abelian gauge invariance. Equations of motion: de Donder gauge and gravitational waves. Comparing to Maxwell's theory.

§IV. Isometries and maximally symmetric spaces

Symmetries of tensors: form-invariance. Killing equations. Integrability condition and maximal number of isometries. The Lie derivative. Killing vectors and conservation laws. The example of Minkowski space. Translational isometries.

§V. Basics of the Schwarschild solution

Schwarzschild metric. Spherical symmetry and Birkhoff's theorem (without proof). Killing vectors of Schwarzschild's metric. Gravitational redshift.

Core Documentation

-Carroll S Spacetime and Geometry: An Introduction to General Relativity (Addison-Wesley 2014/Cambridge University Press, 2019)
-Dirac P A M General Theory of Relativity (Princeton University Press, 1996)
-Hartle S Gravity: An Introduction to Einstein's General Relativity (Cambridge University Press, 2021)
-Rovelli C, General Relativity - the Essentials, (Cambridge University Press, 2021).
-Weinberg S, Gravitation and Cosmology - principles and applications of the general theory of relativity, (John Wiley \& Sons, 1972).

Type of delivery of the course

Blackboard lectures

Type of evaluation

Partials or oral exams

Programme

- Cosmological Principle And Robertson-Walker Metric
- Friedmann Equations
- The Standard Cosmological Model
- Redshift, Cosmological Distances And Cosmological Horizons
- Cosmological Parameters And Their Measurement
- Classical Cosmologial Tests: Hubble Test. Angular Diameter Test. Counts
- Cosmological Constant
- Cosmic Fluids And Their Equation Of State
- Thermal History Of The Universe: Decoupling, Recombination
- Matter-Antimatter Asymmetry
- Beyond Standard Model: Horizon And Flatness Paradoxes, Introduction To Cosmic Inflation
- Dark Matter
- Brief History Of The Universe
- Cosmological Nucleosynthesis
- Matter Dominated Era. Reionization.
- Fcosmic Microwave Background
- Jeans Theory Of Gravitational Instability
- Evolution Of Cosmic Structures
- Spectrum Of Density Perturbations. Linear And Non-Linear Evolution Of The Cosmic Density Field
- Spherical Collapse And Press & Schechter Theory
- Introduction To Numerical Approaches To Structure Formation: N-Body Simultaions
- Key Processes In Galaxy Formation
- Introduction To Open Problems In Structure Formation

Core Documentation

Coles P., Lucchin F. Cosmology [Wiley 2000]
Peebles P.J.E. 1993. Principles of Physical Cosmology [Princeton Series in Physics 1993]

Type of delivery of the course

frontal teaching lessons

Type of evaluation

The exam takes place in oral form The questions cover all the topics of the course.

Programme

§I. Introduction: inertia and covariance

Galilean Relativity and Special Relativity. The Equivalence Principle. Motivations for general covariance. Local inertial frames.

§II. Dynamical spacetime: basics of General Relativity

Curvilinear coordinates. Vectors and tensors under general coordinate transformations. Parallel transport and Christoffel symbols. Covariant derivatives and metric compatibility. Covariantly conserved vectors and conserved vector densities. Transformation of the Christoffel symbols. Ricci's theorem. Geodesics and their Newtonian limit. Time-like, null and space-like curves. Normal coordinates and local inertial frames. Covariant derivation along curves. Riemann curvature tensor. Algebraic properties. Bianchi identities. Local inertial frames. Characterisation of flat spaces. Geodesic deviation. Einstein-Hilbert action and equations of motion. The Palatini identity. Minimal coupling to scalar fields and to Maxwell fields.

§III. Linear approximation and gravitational waves

Motivations. Weak fluctuations over flat space-time: linearised Riemann tensor and its abelian gauge invariance. Equations of motion: de Donder gauge and gravitational waves. Comparing to Maxwell's theory.

§IV. Isometries and maximally symmetric spaces

Symmetries of tensors: form-invariance. Killing equations. Integrability condition and maximal number of isometries. The Lie derivative. Killing vectors and conservation laws. The example of Minkowski space. Translational isometries.

§V. Basics of the Schwarschild solution

Schwarzschild metric. Spherical symmetry and Birkhoff's theorem (without proof). Killing vectors of Schwarzschild's metric. Gravitational redshift.

Core Documentation

-Carroll S Spacetime and Geometry: An Introduction to General Relativity (Addison-Wesley 2014/Cambridge University Press, 2019)
-Dirac P A M General Theory of Relativity (Princeton University Press, 1996)
-Hartle S Gravity: An Introduction to Einstein's General Relativity (Cambridge University Press, 2021)
-Rovelli C, General Relativity - the Essentials, (Cambridge University Press, 2021).
-Weinberg S, Gravitation and Cosmology - principles and applications of the general theory of relativity, (John Wiley \& Sons, 1972).

Type of delivery of the course

Blackboard lectures

Type of evaluation

Partials or oral exams

Programme

- Cosmological Principle And Robertson-Walker Metric
- Friedmann Equations
- The Standard Cosmological Model
- Redshift, Cosmological Distances And Cosmological Horizons
- Cosmological Parameters And Their Measurement
- Classical Cosmologial Tests: Hubble Test. Angular Diameter Test. Counts
- Cosmological Constant
- Cosmic Fluids And Their Equation Of State
- Thermal History Of The Universe: Decoupling, Recombination
- Matter-Antimatter Asymmetry
- Beyond Standard Model: Horizon And Flatness Paradoxes, Introduction To Cosmic Inflation
- Dark Matter
- Brief History Of The Universe
- Cosmological Nucleosynthesis
- Matter Dominated Era. Reionization.
- Fcosmic Microwave Background
- Jeans Theory Of Gravitational Instability
- Evolution Of Cosmic Structures
- Spectrum Of Density Perturbations. Linear And Non-Linear Evolution Of The Cosmic Density Field
- Spherical Collapse And Press & Schechter Theory
- Introduction To Numerical Approaches To Structure Formation: N-Body Simultaions
- Key Processes In Galaxy Formation
- Introduction To Open Problems In Structure Formation

Core Documentation

Coles P., Lucchin F. Cosmology [Wiley 2000]
Peebles P.J.E. 1993. Principles of Physical Cosmology [Princeton Series in Physics 1993]

Type of delivery of the course

frontal teaching lessons

Type of evaluation

The exam takes place in oral form The questions cover all the topics of the course.