The Higgs boson was discovered in 2012 as the last missing piece of the Standard Model of Particle Physics. It is often seen as a key
particle in our search for the origins of dark matter and the matter-antimatter asymmetry. In these lecture, I will cover basic Higgs theory,
the discovery of the Higgs boson, and our state-of-the-art knowledge of the Higgs boson properties, as well as...
In this lecture, we will discuss the basics of dark matter. In particular, we discuss the evidence of dark matter from astrophysical scales to cosmological scales, for instance, galaxy rotation curves, lensing, cosmic microwave background, etc. We then discuss the cosmological origin of dark matter, namely how it is produced in the first few seconds of the universe, how it evolves throughout...
The geometry and topology of supergravity.
The term supergravity refers to a class of gravitational theories invariant under a conjectured symmetry called supersymmetry. Once considered as a potential candidate for a theory of everything, supergravity is nowadays understood as the low energy limit of string theory and as such, supergravity has played a fundamental role in our current...
Title: GW detection with PTAs
Abstract:
In this lecture, we will review the basics of Gravitational Waves (GWs) detection using Pulsar Timing Arrays (PTAs). We will start by discussing how GWs perturb the apparent period of pulsars and derive the famous Hellings and Downs correlation curve describing the correlation of these perturbations among pairs of pulsars. Armed with these results,...
Abstract:
This lecture will provide an overview of some of the main questions of modern research around the Higgs boson at the LHC and future experiments.
A first part of the lectures will discuss the crucial role of the Higgs boson to probe Physics beyond the Standard Model (our current best description of Physics at high energies, but which we know to be only an effective theory of some...
Monte Carlo methods are omnipresent in the physical sciences. Use cases
include, for example, multi-dimensional integration, parameter-space explorations
and Bayesian inference. In this lecture an introduction to Monte Carlo techniques
will be given, including Importance Sampling, Markov Chain Monte Carlo
and Nested Sampling with application examples from high-energy physics to cosmology.
In the advanced dark matter lectures, we cover a specific class of dark matter candidate, wave dark matter. The wave dark matter encompasses a wide range of bosonic dark matter candidates whose mass is smaller than several electron-volt scales. Being that light, it behaves similar to classical waves rather than a particle, offering unique phenomenology across scales. We will discuss some of...
The geometry and topology of supergravity.
In this set of lectures, I will give an introduction to the ongoing quest of discovering the mathematical theory of four-dimensional ungauged supergravity and developing its potential applications to geometry and topology.
In particular, I will use the cohomology of an appropriately chosen locally constant sheaf to implement the Dirac-...
Zoom
https://uni-hamburg.zoom.us/j/64337689760?pwd=aFNwVDN4MnBOTlQxOE4xd3lDMHBSQT09
Meeting-ID: 643 3768 9760
Kenncode: 86228795
Zoom
https://uni-hamburg.zoom.us/j/64337689760?pwd=aFNwVDN4MnBOTlQxOE4xd3lDMHBSQT09
Meeting-ID: 643 3768 9760
Kenncode: 86228795
Mental health services at DESY and UHH by Annette Juchems-Brohl from UHH, Birte Walther from DESY (tbc), and Henriette from QU
Zoom
https://uni-hamburg.zoom.us/j/64337689760?pwd=aFNwVDN4MnBOTlQxOE4xd3lDMHBSQT09
Meeting-ID: 643 3768 9760
Kenncode: 86228795
The Higgs boson was discovered in 2012 as the last missing piece of the Standard Model of Particle Physics. It is often seen as a key
particle in our search for the origins of dark matter and the matter-antimatter asymmetry. In these lecture, I will cover basic Higgs theory,
the discovery of the Higgs boson, and our state-of-the-art knowledge of the Higgs boson properties, as well as...
In this lecture, we will discuss the basics of dark matter. In particular, we discuss the evidence of dark matter from astrophysical scales to cosmological scales, for instance, galaxy rotation curves, lensing, cosmic microwave background, etc. We then discuss the cosmological origin of dark matter, namely how it is produced in the first few seconds of the universe, how it evolves throughout...
The geometry and topology of supergravity.
The term supergravity refers to a class of gravitational theories invariant under a conjectured symmetry called supersymmetry. Once considered as a potential candidate for a theory of everything, supergravity is nowadays understood as the low energy limit of string theory and as such, supergravity has played a fundamental role in our current...
Title: GW detection with PTAs
Abstract:
In this lecture, we will review the basics of Gravitational Waves (GWs) detection using Pulsar Timing Arrays (PTAs). We will start by discussing how GWs perturb the apparent period of pulsars and derive the famous Hellings and Downs correlation curve describing the correlation of these perturbations among pairs of pulsars. Armed with these results,...
This lecture will provide an overview of some of the main questions of modern research around the Higgs boson at the LHC and future experiments.
A first part of the lectures will discuss the crucial role of the Higgs boson to probe Physics beyond the Standard Model (our current best description of Physics at high energies, but which we know to be only an effective theory of some more complete...
In the advanced dark matter lectures, we cover a specific class of dark matter candidate, wave dark matter. The wave dark matter encompasses a wide range of bosonic dark matter candidates whose mass is smaller than several electron-volt scales. Being that light, it behaves similar to classical waves rather than a particle, offering unique phenomenology across scales. We will discuss some of...
The geometry and topology of supergravity.
In this set of lectures, I will give an introduction to the ongoing quest of discovering the mathematical theory of four-dimensional ungauged supergravity and developing its potential applications to geometry and topology.
In particular, I will use the cohomology of an appropriately chosen locally constant sheaf to implement the Dirac-...
Learn how to unlock the secrets to academic time mastery with our power-packed workshop! You will receive directly applicable strategies. Visit this session as your introduction to conquering overwhelming research challenges, defeating procrastination, and optimizing your daily routines for peak productivity.
Key Takeaways:
1. Plan long term: cultivate setting clear goals and have a...
The Higgs boson was discovered in 2012 as the last missing piece of the Standard Model of Particle Physics. It is often seen as a key
particle in our search for the origins of dark matter and the matter-antimatter asymmetry. In these lecture, I will cover basic Higgs theory,
the discovery of the Higgs boson, and our state-of-the-art knowledge of the Higgs boson properties, as well as...
In this lecture, we will discuss the basics of dark matter. In particular, we discuss the evidence of dark matter from astrophysical scales to cosmological scales, for instance, galaxy rotation curves, lensing, cosmic microwave background, etc. We then discuss the cosmological origin of dark matter, namely how it is produced in the first few seconds of the universe, how it evolves throughout...
The geometry and topology of supergravity.
The term supergravity refers to a class of gravitational theories invariant under a conjectured symmetry called supersymmetry. Once considered as a potential candidate for a theory of everything, supergravity is nowadays understood as the low energy limit of string theory and as such, supergravity has played a fundamental role in our current...
Title: GW detection with PTAs
Abstract:
In this lecture, we will review the basics of Gravitational Waves (GWs) detection using Pulsar Timing Arrays (PTAs). We will start by discussing how GWs perturb the apparent period of pulsars and derive the famous Hellings and Downs correlation curve describing the correlation of these perturbations among pairs of pulsars. Armed with these results,...
This lecture will provide an overview of some of the main questions of modern research around the Higgs boson at the LHC and future experiments.
A first part of the lectures will discuss the crucial role of the Higgs boson to probe Physics beyond the Standard Model (our current best description of Physics at high energies, but which we know to be only an effective theory of some more complete...
In the advanced dark matter lectures, we cover a specific class of dark matter candidate, wave dark matter. The wave dark matter encompasses a wide range of bosonic dark matter candidates whose mass is smaller than several electron-volt scales. Being that light, it behaves similar to classical waves rather than a particle, offering unique phenomenology across scales. We will discuss some of...
The geometry and topology of supergravity.
In this set of lectures, I will give an introduction to the ongoing quest of discovering the mathematical theory of four-dimensional ungauged supergravity and developing its potential applications to geometry and topology.
In particular, I will use the cohomology of an appropriately chosen locally constant sheaf to implement the Dirac-...
As academic leaders, your role is to empower your students and group members and help them tap into their full potential to perform at their best.
The academic environment has specific additional requirements as people work under extremely high uncertainty with long periods of delayed gratification and limited resources. With these specific needs in mind, the aim of this skill-building...
invited Alumni:
Bijan Chokoufe Nejad
Nelly Nguyen
Lars Wacker
Thomas Wulf
Zoom-Meeting beitreten
https://uni-hamburg.zoom.us/j/69166819654?pwd=OUVhOWZQNUJ1Kys0eFpLbFBKeC9UZz09
Meeting-ID: 691 6681 9654
Kenncode: 58660305
Zoom-Meeting beitreten
https://uni-hamburg.zoom.us/j/69166819654?pwd=OUVhOWZQNUJ1Kys0eFpLbFBKeC9UZz09
Meeting-ID: 691 6681 9654
Kenncode: 58660305
Zoom-Meeting beitreten
https://uni-hamburg.zoom.us/j/69166819654?pwd=OUVhOWZQNUJ1Kys0eFpLbFBKeC9UZz09
Meeting-ID: 691 6681 9654
Kenncode: 58660305
Zoom-Meeting beitreten
https://uni-hamburg.zoom.us/j/69166819654?pwd=OUVhOWZQNUJ1Kys0eFpLbFBKeC9UZz09
Meeting-ID: 691 6681 9654
Kenncode: 58660305
Zoom-Meeting beitreten
https://uni-hamburg.zoom.us/j/69166819654?pwd=OUVhOWZQNUJ1Kys0eFpLbFBKeC9UZz09
Meeting-ID: 691 6681 9654
Kenncode: 58660305
Zoom-Meeting beitreten
https://uni-hamburg.zoom.us/j/69166819654?pwd=OUVhOWZQNUJ1Kys0eFpLbFBKeC9UZz09
Meeting-ID: 691 6681 9654
Kenncode: 58660305
Zoom-Meeting beitreten
https://uni-hamburg.zoom.us/j/69166819654?pwd=OUVhOWZQNUJ1Kys0eFpLbFBKeC9UZz09
Meeting-ID: 691 6681 9654
Kenncode: 58660305
Zoom-Meeting beitreten
https://uni-hamburg.zoom.us/j/69166819654?pwd=OUVhOWZQNUJ1Kys0eFpLbFBKeC9UZz09
Meeting-ID: 691 6681 9654
Kenncode: 58660305
Zoom-Meeting beitreten
https://uni-hamburg.zoom.us/j/69166819654?pwd=OUVhOWZQNUJ1Kys0eFpLbFBKeC9UZz09
Meeting-ID: 691 6681 9654
Kenncode: 58660305
Zoom-Meeting beitreten
https://uni-hamburg.zoom.us/j/69166819654?pwd=OUVhOWZQNUJ1Kys0eFpLbFBKeC9UZz09
Meeting-ID: 691 6681 9654
Kenncode: 58660305
