Class description: This is the course webpage for the Spring 2023 lectures of "Physical Cosmology" offered by the University of Zurich. In this course (formerly known as Theoretical Cosmology), we study the history of our Universe on large scales. We first discuss key cosmological observations that led to our standard model of cosmology, and we study in detail the origin and the evolution of the Universe such as inflation, big bang nucleosynthesis, and cosmic microwave background anisotropies. In the second part we learn (relativistic) perturbation theory and apply it to initial conditions, large-scale structure and weak gravitational lensing. The course and exercise classes will be presented in English.

The lectures will be held separately from ETH. A different class under the same name will be taught by a different lecturer at ETH.

Lectures by: Prof. Dr. Jaiyul Yoo (jyoo physik.uzh.ch)

Teaching assistants: Lara Bohnenblust (lara.bohnenblust uzh.ch) and Matteo Magi (matteo.magi uzh.ch)

Prerequisites: Basic knowledge of general relativity is required

About the course: The course will focus on applying General Relativity to Cosmology as well as developing the modern theory of structure formation in a cold dark matter Universe. The syllabus consists of the following topics:

Part I: Homogeneous and Isotropic Universe

1. Introduction: dynamics of expanding Universe and its matter/energy content
2. The FRW metric and Friedmann equations
3. The Thermal History of the Universe (Hot Big Bang model)
4. Decoupling and Thermodynamics of relic particles
5. Nucleosynthesis and Recombination
6. Introduction to Inflationary Theory

1. Newtonian Perturbation Theory
2. Probes of Inhomogeneities
3. Relativistic Perturbation Theory
4. Standard Inflationary Models
5. Weak gravitational lensing
6. Cosmic microwave background anisotropies (time permitted)

• Lecture 1: Introduction (slides)
• Lecture 2: Redshift and Hubble law (pdf)
• Lectures 3 - 4: Robertson-Walker metric, Energy-momentum tensor, Friedman equation (pdf)
• Lectures 5 - 6: Distance ladder (slides, pdf), cosmological constant (pdf)
• Lectures 7 - 8: History of the Early Universe, Thermal equilibrium
• Lectures 9 - 10: Relic abundance, Big Bang Nucleosynthesis (slides)
• Lecture 11: Cosmic Recombination and Decoupling

• Lectures 12: Introduction (slides)
• Lectures 13 - 14: Newtonian perturbation theory (note), initial conditions, two-point correlation function, the power spectrum (pdf)
• Lectures 15 - 16: The shape of the matter power spectrum (note), Peculiar velocity, Redshift space-distortion (note)
• Lectures 17 - 18: Spherical collapse model, Relativistic perturbation theory (pdf)
• Lectures 19 - 20: Gauge transformations, Einstein equations
• Lectures 21 - 23: Standard inflationary model, background dynamics, slow-roll parameters (note) (pdf)
• Lectures 24 - 26: Gravitational lensing (strong, micro, weak), lens equation (slides), projected potential, shape distortion, ellipticity (note) (pdf)
• Lecture 27: Summary

• Problem sheet 0: pdf
• Problem sheet 1 & 2: pdf
• Problem sheet 3: pdf
• Problem sheet 4: pdf
• Problem sheet 5: pdf
• Problem sheet 6: pdf
• Problem sheet 7: pdf
• Problem sheet 8: pdf
• Problem sheet 9: pdf
• Problem sheet 10: pdf

• Solution sheet 0: pdf
• Solution sheet 1 & 2: pdf
• Solution sheet 3: pdf
• Solution sheet 4: pdf
• Solution sheet 5: pdf
• Solution sheet 6: pdf
• Solution sheet 7: pdf
• Solution sheet 8: pdf
• Solution sheet 9: pdf