Error message

Monday, 30 May 2022

Bernhard Müller
Title: Evolution of Massive Stars (Lecture 1)
Abstract:

Core-collapse supernovae, the explosions of massive stars, are of pivotal importance for understanding the population of neutron star and black hole binary systems whose mergers can now be observed by gravitational detectors. These spectacular explosions are also promising targets for multi-messenger observations in their own right.

These lectures will discuss relevant physical principles that underlie our current understanding of supernova dynamics, multi-messenger observables, and phenomenology.

The lectures will cover the following topics:

- Outline of massive star evolution and outlook on unresolved questions

- Dynamics of collapse and explosion and overview of supernova explosion modelling

- Gravitational waves from supernovae

- Neutrinos from supernovae

- Supernova nucleosynthesis

- Phenomenology of Observed Supernovae and Compact Remnants

Tuesday, 31 May 2022

Bernhard Müller
Title: Core-Collapse Supernova Dynamics (Lecture 2)
Abstract:

Core-collapse supernovae, the explosions of massive stars, are of pivotal importance for understanding the population of neutron star and black hole binary systems whose mergers can now be observed by gravitational detectors. These spectacular explosions are also promising targets for multi-messenger observations in their own right.

These lectures will discuss relevant physical principles that underlie our current understanding of supernova dynamics, multi-messenger observables, and phenomenology.

The lectures will cover the following topics:

- Outline of massive star evolution and outlook on unresolved questions

- Dynamics of collapse and explosion and overview of supernova explosion modelling

- Gravitational waves from supernovae

- Neutrinos from supernovae

- Supernova nucleosynthesis

- Phenomenology of Observed Supernovae and Compact Remnants

Wednesday, 01 June 2022

Bernhard Müller
Title: Neutrinos and Gravitational Waves from Core-Collapse Supernovae (Lecture 3)
Abstract:

Core-collapse supernovae, the explosions of massive stars, are of pivotal importance for understanding the population of neutron star and black hole binary systems whose mergers can now be observed by gravitational detectors. These spectacular explosions are also promising targets for multi-messenger observations in their own right.

These lectures will discuss relevant physical principles that underlie our current understanding of supernova dynamics, multi-messenger observables, and phenomenology.

The lectures will cover the following topics:

- Outline of massive star evolution and outlook on unresolved questions

- Dynamics of collapse and explosion and overview of supernova explosion modelling

- Gravitational waves from supernovae

- Neutrinos from supernovae

- Supernova nucleosynthesis

- Phenomenology of Observed Supernovae and Compact Remnants

Thursday, 02 June 2022

Bernhard Müller
Title: Nucleosynthesis in Massive Stars and Core-Collapse Supernovae (Lecture 4)
Abstract:

Core-collapse supernovae, the explosions of massive stars, are of pivotal importance for understanding the population of neutron star and black hole binary systems whose mergers can now be observed by gravitational detectors. These spectacular explosions are also promising targets for multi-messenger observations in their own right.

These lectures will discuss relevant physical principles that underlie our current understanding of supernova dynamics, multi-messenger observables, and phenomenology.

The lectures will cover the following topics:

- Outline of massive star evolution and outlook on unresolved questions

- Dynamics of collapse and explosion and overview of supernova explosion modelling

- Gravitational waves from supernovae

- Neutrinos from supernovae

- Supernova nucleosynthesis

- Phenomenology of Observed Supernovae and Compact Remnants

Friday, 03 June 2022

Bernhard Müller
Title: Basics of Core-Collapse Supernova Phenomenology (Lecture 5)
Abstract:

Core-collapse supernovae, the explosions of massive stars, are of pivotal importance for understanding the population of neutron star and black hole binary systems whose mergers can now be observed by gravitational detectors. These spectacular explosions are also promising targets for multi-messenger observations in their own right.

These lectures will discuss relevant physical principles that underlie our current understanding of supernova dynamics, multi-messenger observables, and phenomenology.

The lectures will cover the following topics:

- Outline of massive star evolution and outlook on unresolved questions

- Dynamics of collapse and explosion and overview of supernova explosion modelling

- Gravitational waves from supernovae

- Neutrinos from supernovae

- Supernova nucleosynthesis

- Phenomenology of Observed Supernovae and Compact Remnants

Monday, 06 June 2022

Christopher Berry
Title: Compact Binary Evolution, Rates and Population Modelling (Lecture 1)
Abstract:
  1. Compact binary astrophysics
    1. Forming merging binaries
    2. Physics of binary evolution
  2. Gravitational-wave data analysis
    1. Introduction to data analysis
    2. Population inference
  3. Current results

Tuesday, 07 June 2022

Christopher Berry
Title: Compact Binary Evolution, Rates and Population Modelling (Lecture 2)
Abstract:
  1. Compact binary astrophysics
    1. Forming merging binaries
    2. Physics of binary evolution
  2. Gravitational-wave data analysis
    1. Introduction to data analysis
    2. Population inference
  3. Current results
Christopher Berry
Title: Compact Binary Evolution, Rates and Population Modelling (Lecture 3)
Abstract:
  1. Compact binary astrophysics
    1. Forming merging binaries
    2. Physics of binary evolution
  2. Gravitational-wave data analysis
    1. Introduction to data analysis
    2. Population inference
  3. Current results

Wednesday, 08 June 2022

Christopher Berry
Title: Compact Binary Evolution, Rates and Population Modelling (Lecture 4)
Abstract:
  1. Compact binary astrophysics
    1. Forming merging binaries
    2. Physics of binary evolution
  2. Gravitational-wave data analysis
    1. Introduction to data analysis
    2. Population inference
  3. Current results

Friday, 10 June 2022

Christopher Berry
Title: Compact Binary Evolution, Rates and Population Modelling (Lecture 5)
Abstract:
  1. Compact binary astrophysics
    1. Forming merging binaries
    2. Physics of binary evolution
  2. Gravitational-wave data analysis
    1. Introduction to data analysis
    2. Population inference
  3. Current results