Talks

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Summer School on Gravitational-Wave Astronomy
Monday, 29 June 2015
Time Speaker Title Resources
09:30 to 11:00 Patrick Dasgupta (University of Delhi, India) Introduction to the theory of GWs
 
11:00 to 11:30 -- Tea / Coffee
11:30 to 13:00 Peter Saulson (Syracuse University, USA) Gravitational waves and their interaction with detectors
   
13:00 to 14:00 -- Lunch
14:00 to 16:00 Patrick Dasgupta (University of Delhi, India) Tutorial 1
16:00 to 18:30 Peter Saulson (Syracuse University, USA) Tutorial 1
18:30 to 19:30 -- Dinner
Tuesday, 30 June 2015
Time Speaker Title Resources
09:30 to 11:00 Patrick Dasgupta (University of Delhi, India) Introduction to the theory of GWs
 
11:00 to 11:30 -- Tea / Coffee
11:30 to 13:00 Peter Saulson (Syracuse University, USA) Shot noise and radiation pressure noise: semi-classical treatment
   
13:00 to 14:00 -- Lunch
14:00 to 16:00 Patrick Dasgupta (University of Delhi, India) Tutorial 2
16:00 to 18:30 Peter Saulson (Syracuse University, USA) Tutorial 2
18:30 to 19:30 -- Dinner
Wednesday, 01 July 2015
Time Speaker Title Resources
09:30 to 11:00 Bala Iyer (ICTS, India) Beyond linear approximation to GR for GW detection
   
11:00 to 11:30 -- Tea / Coffee
11:30 to 13:00 Peter Saulson (Syracuse University, USA) Mathematical methods of experimental physics
   
13:00 to 14:00 -- Lunch
14:00 to 16:00 KG Arun (CMI, India) Tutorial 1
16:00 to 18:30 Peter Saulson (Syracuse University, USA) Tutorial 3: Vibration isolation
 
18:30 to 19:30 -- Dinner
Thursday, 02 July 2015
Time Speaker Title Resources
09:30 to 11:00 Bala Iyer (ICTS, India) Beyond linear approximation to GR for GW detection
 
11:00 to 11:30 -- Tea / Coffee
11:30 to 13:00 Peter Saulson (Syracuse University, USA) Thermal noise
   
13:00 to 14:00 -- Lunch
14:00 to 16:00 KG Arun (CMI, India) Tutorial 2
16:00 to 18:30 Peter Saulson (Syracuse University, USA) Tutorial 4
18:30 to 19:30 -- Dinner
Friday, 03 July 2015
Time Speaker Title Resources
09:30 to 11:00 Bala Iyer (ICTS, India) Beyond linear approximation to GR for GW detection
 
11:00 to 11:30 -- Tea / Coffee
11:30 to 13:00 Peter Saulson (Syracuse University, USA) Feedback control systems
   
13:00 to 14:00 -- Lunch
14:00 to 16:00 KG Arun (CMI, India) Tutorial 3
16:00 to 18:30 Peter Saulson (Syracuse University, USA) Tutorial 5
18:30 to 19:30 -- Dinner
Monday, 06 July 2015
Time Speaker Title Resources
09:30 to 11:00 Cole Miller (University of Maryland, USA) Introduction to astrophysics and gravitational waves, and order of magnitude estimates
   
11:00 to 11:30 -- Tea / Coffee
11:30 to 13:00 Chris Van Den Broeck (Nikhef, Netherlands) The detection and interpretation of gravitational waves: Introduction
   
13:00 to 14:00 -- Lunch
14:00 to 16:00 Cole Miller (University of Maryland, USA) Tutorial 1: Introduction
 
16:00 to 18:30 Chris Van Den Broeck (Nikhef, Netherlands) Tutorial 1
18:30 to 19:30 -- Dinner
Tuesday, 07 July 2015
Time Speaker Title Resources
09:30 to 11:00 Cole Miller (University of Maryland, USA) Black holes
   
11:00 to 11:30 -- Tea / Coffee
11:30 to 13:00 Chris Van Den Broeck (Nikhef, Netherlands) Gravitational wave data analysis: Detection
   
13:00 to 14:00 -- Lunch
14:00 to 16:00 Cole Miller (University of Maryland, USA) Tutorial 2: Black holes
 
16:00 to 18:30 Chris Van Den Broeck (Nikhef, Netherlands) Tutorial 2: GW signals as seen in a detector
 
18:30 to 19:30 -- Dinner
Wednesday, 08 July 2015
Time Speaker Title Resources
09:30 to 11:00 Cole Miller (University of Maryland, USA) Neutron stars
   
11:00 to 11:30 -- Tea / Coffee
11:30 to 13:00 Chris Van Den Broeck (Nikhef, Netherlands) Bayesian model selection and parameter estimation
   
13:00 to 14:00 -- Lunch
14:00 to 16:00 Cole Miller (University of Maryland, USA) Tutorial 3: Neutron stars
 
16:00 to 18:30 Chris Van Den Broeck (Nikhef, Netherlands) Tutorial 3: Matched filtering
 
18:30 to 19:30 -- Dinner
Thursday, 09 July 2015
Time Speaker Title Resources
09:30 to 11:00 Cole Miller (University of Maryland, USA ) Binaries
   
11:00 to 11:30 -- Tea / Coffee
11:30 to 13:00 Chris Van Den Broeck (Nikhef, Netherlands) Bayesian model selection and parameter estimation
   
13:00 to 14:00 -- Lunch
14:00 to 16:00 Cole Miller (University of Maryland, USA) Tutorial 4: Binaries
 
16:00 to 18:30 Chris Van Den Broeck (Nikhef, Netherlands) Tutorial 4: Nested sampling
 
18:30 to 19:30 -- Dinner
Friday, 10 July 2015
Time Speaker Title Resources
09:30 to 11:00 Cole Miller (University of Maryland, USA) Continuous sources, bursts, and stochastic sources
   
11:00 to 11:30 -- Tea / Coffee
11:30 to 13:00 Chris Van Den Broeck (Nikhef, Netherlands) Testing general relativity with gravitational waves
   
13:00 to 14:00 -- Lunch
14:00 to 16:00 Cole Miller (University of Maryland, USA) Tutorial 5: Continuous sources, bursts, and stochastic sources
 
16:00 to 18:30 Chris Van Den Broeck (Nikhef, Netherlands) Tutorial 5: Nested sampling
18:30 to 19:30 -- Dinner
Monday, 15 July 2019
Time Speaker Title Resources
11:00 to 11:30 -- Tea/coffee break
11:30 to 13:00 Sudipta Sarkar (IITG, India) Course 2 Advanced course in general relativity (Lecture 1)

Riemann, Ricci and Einstein Tensor, the Einstein field equation, Energy-Momentum tensor, Spherically symmetric asymptotically flat vacuum solution, The Schwarzschild Geometry, Eddington-Finkelstein coordinates. Timelike geodesics of Schwarzschild Geometry. Effective potential and nature of timelike obits. Null geodesics, Photon Sphere and shadow of Schwarzschild black hole. Introduction to Kerr solution. Dragging of Inertial Frames & ZAMO, Ergosphere, and the event horizon, Penrose Process.  Linearized Einstein Equation. Gauge freedoms, Gravitational radiation, Energy loss by gravitation wave emission.

References: 

  1. Sean Carrol, Lectures notes on general relativity (gr-qc/9712019) 
  2. Eric Poisson, A Relativist’s Toolkit (Cambridge University Press) 
  3. S Chandrasekhar, The Mathematical Theory of Black Holes (Oxford)
 
13:00 to 14:00 - Lunch
16:00 to 17:30 Sudipta Sarkar (IITG, India) Course 2 Advanced course in general relativity

Riemann, Ricci and Einstein Tensor, the Einstein field equation, Energy-Momentum tensor, Spherically symmetric asymptotically flat vacuum solution, The Schwarzschild Geometry, Eddington-Finkelstein coordinates. Timelike geodesics of Schwarzschild Geometry. Effective potential and nature of timelike obits. Null geodesics, Photon Sphere and shadow of Schwarzschild black hole. Introduction to Kerr solution. Dragging of Inertial Frames & ZAMO, Ergosphere, and the event horizon, Penrose Process.  Linearized Einstein Equation. Gauge freedoms, Gravitational radiation, Energy loss by gravitation wave emission.

References: 

  1. Sean Carrol, Lectures notes on general relativity (gr-qc/9712019) 
  2. Eric Poisson, A Relativist’s Toolkit (Cambridge University Press) 
  3. S Chandrasekhar, The Mathematical Theory of Black Holes (Oxford)
Tuesday, 16 July 2019
Time Speaker Title Resources
09:30 to 11:00 Teruaki Suyama (Tokyo Institute of Technology, Japan) Course 1 Primordial black holes and gravitational wave astronomy

Introduction: Why primordial black holes (PBHs) are important in cosmology. Formation of PBHs: Threshold of the PBH formation, abundance of PBHs, generating seeds of PBH from inflation. Observational constraints on the abundance of PBHs. PBHs as sources of gravitational waves:Mechanism of the PBH binary formation, merger rate, tests of the PBH hypothesis by the future GW observations

References: 

  1. M. Sasaki et al, Class. Quant. Grav. 35 (2018), 063001 [arXiv:1801.05235]
11:00 to 11:30 - Tea/coffee break
11:30 to 13:00 Sudipta Sarkar (IITG, India) Course 2 Advanced course in general relativity (Lecture 2)

Riemann, Ricci and Einstein Tensor, the Einstein field equation, Energy-Momentum tensor, Spherically symmetric asymptotically flat vacuum solution, The Schwarzschild Geometry, Eddington-Finkelstein coordinates. Timelike geodesics of Schwarzschild Geometry. Effective potential and nature of timelike obits. Null geodesics, Photon Sphere and shadow of Schwarzschild black hole. Introduction to Kerr solution. Dragging of Inertial Frames & ZAMO, Ergosphere, and the event horizon, Penrose Process.  Linearized Einstein Equation. Gauge freedoms, Gravitational radiation, Energy loss by gravitation wave emission.

References: 

  1. Sean Carrol, Lectures notes on general relativity (gr-qc/9712019) 
  2. Eric Poisson, A Relativist’s Toolkit (Cambridge University Press) 
  3. S Chandrasekhar, The Mathematical Theory of Black Holes (Oxford)
 
13:00 to 14:00 - Lunch
14:00 to 15:30 Teruaki Suyama (Tokyo Institute of Technology, Japan) Course 1 Primordial black holes and gravitational wave astronomy

ntroduction: Why primordial black holes (PBHs) are important in cosmology. Formation of PBHs: Threshold of the PBH formation, abundance of PBHs, generating seeds of PBH from inflation. Observational constraints on the abundance of PBHs. PBHs as sources of gravitational waves:Mechanism of the PBH binary formation, merger rate, tests of the PBH hypothesis by the future GW observations

References: 

  1. M. Sasaki et al, Class. Quant. Grav. 35 (2018), 063001 [arXiv:1801.05235]
15:30 to 16:00 - Tea/coffee break
16:00 to 17:30 Sudipta Sarkar (IITG, India) Course 2 Advanced course in general relativity

Riemann, Ricci and Einstein Tensor, the Einstein field equation, Energy-Momentum tensor, Spherically symmetric asymptotically flat vacuum solution, The Schwarzschild Geometry, Eddington-Finkelstein coordinates. Timelike geodesics of Schwarzschild Geometry. Effective potential and nature of timelike obits. Null geodesics, Photon Sphere and shadow of Schwarzschild black hole. Introduction to Kerr solution. Dragging of Inertial Frames & ZAMO, Ergosphere, and the event horizon, Penrose Process.  Linearized Einstein Equation. Gauge freedoms, Gravitational radiation, Energy loss by gravitation wave emission.

References: 

  1. Sean Carrol, Lectures notes on general relativity (gr-qc/9712019) 
  2. Eric Poisson, A Relativist’s Toolkit (Cambridge University Press) 
  3. S Chandrasekhar, The Mathematical Theory of Black Holes (Oxford)
Wednesday, 17 July 2019
Time Speaker Title Resources
09:30 to 11:00 Teruaki Suyama (Tokyo Institute of Technology, Japan) Course 1 Primordial black holes and gravitational wave astronomy

ntroduction: Why primordial black holes (PBHs) are important in cosmology. Formation of PBHs: Threshold of the PBH formation, abundance of PBHs, generating seeds of PBH from inflation. Observational constraints on the abundance of PBHs. PBHs as sources of gravitational waves:Mechanism of the PBH binary formation, merger rate, tests of the PBH hypothesis by the future GW observations

References: 

  1. M. Sasaki et al, Class. Quant. Grav. 35 (2018), 063001 [arXiv:1801.05235]
11:00 to 11:30 - Tea/coffee break
11:30 to 13:00 Sudipta Sarkar (IITG, India) Course 2 Advanced course in general relativity (Lecture 3)

Riemann, Ricci and Einstein Tensor, the Einstein field equation, Energy-Momentum tensor, Spherically symmetric asymptotically flat vacuum solution, The Schwarzschild Geometry, Eddington-Finkelstein coordinates. Timelike geodesics of Schwarzschild Geometry. Effective potential and nature of timelike obits. Null geodesics, Photon Sphere and shadow of Schwarzschild black hole. Introduction to Kerr solution. Dragging of Inertial Frames & ZAMO, Ergosphere, and the event horizon, Penrose Process.  Linearized Einstein Equation. Gauge freedoms, Gravitational radiation, Energy loss by gravitation wave emission.

References: 

  1. Sean Carrol, Lectures notes on general relativity (gr-qc/9712019) 
  2. Eric Poisson, A Relativist’s Toolkit (Cambridge University Press) 
  3. S Chandrasekhar, The Mathematical Theory of Black Holes (Oxford)
 
13:00 to 14:00 - Lunch
14:00 to 15:30 Teruaki Suyama (Tokyo Institute of Technology, Japan) Course 1 Primordial black holes and gravitational wave astronomy

Introduction: Why primordial black holes (PBHs) are important in cosmology. Formation of PBHs: Threshold of the PBH formation, abundance of PBHs, generating seeds of PBH from inflation. Observational constraints on the abundance of PBHs. PBHs as sources of gravitational waves:Mechanism of the PBH binary formation, merger rate, tests of the PBH hypothesis by the future GW observations

References: 

  1. M. Sasaki et al, Class. Quant. Grav. 35 (2018), 063001 [arXiv:1801.05235]
16:00 to 17:30 Sudipta Sarkar (IITG, India) Course 2 Advanced course in general relativity

Riemann, Ricci and Einstein Tensor, the Einstein field equation, Energy-Momentum tensor, Spherically symmetric asymptotically flat vacuum solution, The Schwarzschild Geometry, Eddington-Finkelstein coordinates. Timelike geodesics of Schwarzschild Geometry. Effective potential and nature of timelike obits. Null geodesics, Photon Sphere and shadow of Schwarzschild black hole. Introduction to Kerr solution. Dragging of Inertial Frames & ZAMO, Ergosphere, and the event horizon, Penrose Process.  Linearized Einstein Equation. Gauge freedoms, Gravitational radiation, Energy loss by gravitation wave emission.

References: 

  1. Sean Carrol, Lectures notes on general relativity (gr-qc/9712019) 
  2. Eric Poisson, A Relativist’s Toolkit (Cambridge University Press) 
  3. S Chandrasekhar, The Mathematical Theory of Black Holes (Oxford)
Thursday, 18 July 2019
Time Speaker Title Resources
09:30 to 11:00 Teruaki Suyama (Tokyo Institute of Technology, Japan) Course 1 Primordial black holes and gravitational wave astronomy

Introduction: Why primordial black holes (PBHs) are important in cosmology. Formation of PBHs: Threshold of the PBH formation, abundance of PBHs, generating seeds of PBH from inflation. Observational constraints on the abundance of PBHs. PBHs as sources of gravitational waves:Mechanism of the PBH binary formation, merger rate, tests of the PBH hypothesis by the future GW observations

References: 

  1. M. Sasaki et al, Class. Quant. Grav. 35 (2018), 063001 [arXiv:1801.05235]
11:00 to 11:30 - Tea/coffee break
11:30 to 13:00 Sudipta Sarkar (IITG, India) Course 2 Advanced course in general relativity (Lecture 4)

Riemann, Ricci and Einstein Tensor, the Einstein field equation, Energy-Momentum tensor, Spherically symmetric asymptotically flat vacuum solution, The Schwarzschild Geometry, Eddington-Finkelstein coordinates. Timelike geodesics of Schwarzschild Geometry. Effective potential and nature of timelike obits. Null geodesics, Photon Sphere and shadow of Schwarzschild black hole. Introduction to Kerr solution. Dragging of Inertial Frames & ZAMO, Ergosphere, and the event horizon, Penrose Process.  Linearized Einstein Equation. Gauge freedoms, Gravitational radiation, Energy loss by gravitation wave emission.

References: 

  1. Sean Carrol, Lectures notes on general relativity (gr-qc/9712019) 
  2. Eric Poisson, A Relativist’s Toolkit (Cambridge University Press) 
  3. S Chandrasekhar, The Mathematical Theory of Black Holes (Oxford)
 
13:00 to 14:00 - Lunch
14:00 to 15:30 Teruaki Suyama (Tokyo Institute of Technology, Japan) Course 1 Primordial black holes and gravitational wave astronomy

Introduction: Why primordial black holes (PBHs) are important in cosmology. Formation of PBHs: Threshold of the PBH formation, abundance of PBHs, generating seeds of PBH from inflation. Observational constraints on the abundance of PBHs. PBHs as sources of gravitational waves:Mechanism of the PBH binary formation, merger rate, tests of the PBH hypothesis by the future GW observations

References: 

  1. M. Sasaki et al, Class. Quant. Grav. 35 (2018), 063001 [arXiv:1801.05235]
15:30 to 16:00 - Tea/coffee break
16:00 to 17:30 Sudipta Sarkar (IITG, India) Course 2 Advanced course in general relativity

Riemann, Ricci and Einstein Tensor, the Einstein field equation, Energy-Momentum tensor, Spherically symmetric asymptotically flat vacuum solution, The Schwarzschild Geometry, Eddington-Finkelstein coordinates. Timelike geodesics of Schwarzschild Geometry. Effective potential and nature of timelike obits. Null geodesics, Photon Sphere and shadow of Schwarzschild black hole. Introduction to Kerr solution. Dragging of Inertial Frames & ZAMO, Ergosphere, and the event horizon, Penrose Process.  Linearized Einstein Equation. Gauge freedoms, Gravitational radiation, Energy loss by gravitation wave emission.

References: 

  1. Sean Carrol, Lectures notes on general relativity (gr-qc/9712019) 
  2. Eric Poisson, A Relativist’s Toolkit (Cambridge University Press) 
  3. S Chandrasekhar, The Mathematical Theory of Black Holes (Oxford)
Friday, 19 July 2019
Time Speaker Title Resources
09:30 to 11:00 Teruaki Suyama (Tokyo Institute of Technology, Japan) Course 1 Primordial black holes and gravitational wave astronomy

Introduction: Why primordial black holes (PBHs) are important in cosmology. Formation of PBHs: Threshold of the PBH formation, abundance of PBHs, generating seeds of PBH from inflation. Observational constraints on the abundance of PBHs. PBHs as sources of gravitational waves:Mechanism of the PBH binary formation, merger rate, tests of the PBH hypothesis by the future GW observations

References: 

  1. M. Sasaki et al, Class. Quant. Grav. 35 (2018), 063001 [arXiv:1801.05235]
11:00 to 11:30 - Tea/coffee break
13:00 to 14:00 - LUnch
14:00 to 15:30 Teruaki Suyama (Tokyo Institute of Technology, Japan) Course 1 Primordial black holes and gravitational wave astronomy

Introduction: Why primordial black holes (PBHs) are important in cosmology. Formation of PBHs: Threshold of the PBH formation, abundance of PBHs, generating seeds of PBH from inflation. Observational constraints on the abundance of PBHs. PBHs as sources of gravitational waves:Mechanism of the PBH binary formation, merger rate, tests of the PBH hypothesis by the future GW observations

References: 

  1. M. Sasaki et al, Class. Quant. Grav. 35 (2018), 063001 [arXiv:1801.05235]
15:30 to 16:00 - Tea/coffee break
16:00 to 17:30 Sudipta Sarkar (IITG, India) Course 2 Advanced course in general relativity

Riemann, Ricci and Einstein Tensor, the Einstein field equation, Energy-Momentum tensor, Spherically symmetric asymptotically flat vacuum solution, The Schwarzschild Geometry, Eddington-Finkelstein coordinates. Timelike geodesics of Schwarzschild Geometry. Effective potential and nature of timelike obits. Null geodesics, Photon Sphere and shadow of Schwarzschild black hole. Introduction to Kerr solution. Dragging of Inertial Frames & ZAMO, Ergosphere, and the event horizon, Penrose Process.  Linearized Einstein Equation. Gauge freedoms, Gravitational radiation, Energy loss by gravitation wave emission.

References: 

  1. Sean Carrol, Lectures notes on general relativity (gr-qc/9712019) 
  2. Eric Poisson, A Relativist’s Toolkit (Cambridge University Press) 
  3. S Chandrasekhar, The Mathematical Theory of Black Holes (Oxford)
Monday, 22 July 2019
Time Speaker Title Resources
09:30 to 11:00 Luc Blanchet (Institute of Astrophysics, France) Course 3 Gravitational radiation from post-Newtonian sources and inspiralling compact binaries (Lecture 1)

Quadrupole formula, effect of GWs on matter, problem of the generation of GWs; and more advanced ones: post-Newtonian methods, the multipolar post-Minkowskian expansion, problem of motion, applications to compact binary systems, Fokker Lagrangian and Hamiltonian, effects of spins and internal structure.

References: 

  1. L. Blanchet, Living Rev. Relativ. (2014) 17: 2. https://doi.org/10.12942/lrr-2014-2
 
11:00 to 11:30 - Tea/coffee break
11:30 to 13:00 Adam Pound (University of Southampton, UK) Course 4 Self-force and radiation reaction in general relativity (Lecture 1)

Overview of extreme mass ratio inspirals.  Perturbation theory in GR. Orbital dynamics in Schwarzschild and Kerr spacetime. The adiabatic approximation. Foundations of self-force theory: matched asymptotic expansions. Practical methods: puncture scheme and mode-sum regularization. 

References: 

  1. Leor Barack, Adam Pound, Self-force and radiation reaction in general relativity, arXiv:1805.10385 [gr-qc]. 
 
13:00 to 14:00 - Lunch
14:00 to 15:30 Luc Blanchet (Institute of Astrophysics, France) Course 3 Gravitational radiation from post-Newtonian sources and inspiralling compact binaries

Quadrupole formula, effect of GWs on matter, problem of the generation of GWs; and more advanced ones: post-Newtonian methods, the multipolar post-Minkowskian expansion, problem of motion, applications to compact binary systems, Fokker Lagrangian and Hamiltonian, effects of spins and internal structure.

References: 

  1. L. Blanchet, Living Rev. Relativ. (2014) 17: 2. https://doi.org/10.12942/lrr-2014-2

Preparatory material: 

  1. Kip S. Thorne, "Gravitational Radiation," in Three Hundred Years of Gravitation, ed. S.W. Hawking and W. Israel (Cambridge University Press, 1987), pp. 330-458.
  2. Michele Maggiore, Gravitational Waves: Volume 1: Theory and Experiments (Cambridge University Press)
  3. Misner, Thorne, Wheeler, Gravitation (Princeton University Press) [Chapters 18 (weak gravitational fields), 35 (propagation of GWs), 36 (generation of GWs) and Exercises: 35.1, 35.2, 35.15, 36.2, 36.5, 36.6, 36.8, 36.9]
15:30 to 16:00 - Tea/coffee break
16:00 to 17:30 Adam Pound (University of Southampton, UK) Course 4 Self-force and radiation reaction in general relativity

Overview of extreme mass ratio inspirals.  Perturbation theory in GR. Orbital dynamics in Schwarzschild and Kerr spacetime. The adiabatic approximation. Foundations of self-force theory: matched asymptotic expansions. Practical methods: puncture scheme and mode-sum regularization. 

References: 

  1. Leor Barack, Adam Pound, Self-force and radiation reaction in general relativity, arXiv:1805.10385 [gr-qc]. 
Tuesday, 23 July 2019
Time Speaker Title Resources
09:30 to 11:00 Luc Blanchet (Institute of Astrophysics, France) Course 3 Gravitational radiation from post-Newtonian sources and inspiralling compact binaries (Lecture 2)

Quadrupole formula, effect of GWs on matter, problem of the generation of GWs; and more advanced ones: post-Newtonian methods, the multipolar post-Minkowskian expansion, problem of motion, applications to compact binary systems, Fokker Lagrangian and Hamiltonian, effects of spins and internal structure.

References: 

  1. L. Blanchet, Living Rev. Relativ. (2014) 17: 2. https://doi.org/10.12942/lrr-2014-2

Preparatory material: 

  1. Kip S. Thorne, "Gravitational Radiation," in Three Hundred Years of Gravitation, ed. S.W. Hawking and W. Israel (Cambridge University Press, 1987), pp. 330-458.
  2. Michele Maggiore, Gravitational Waves: Volume 1: Theory and Experiments (Cambridge University Press)
  3. Misner, Thorne, Wheeler, Gravitation (Princeton University Press) [Chapters 18 (weak gravitational fields), 35 (propagation of GWs), 36 (generation of GWs) and Exercises: 35.1, 35.2, 35.15, 36.2, 36.5, 36.6, 36.8, 36.9]
 
11:00 to 11:30 - Tea/coffee break
11:30 to 13:00 Adam Pound (University of Southampton, UK) Course 4 Self-force and radiation reaction in general relativity (Lecture 2)

Overview of extreme mass ratio inspirals.  Perturbation theory in GR. Orbital dynamics in Schwarzschild and Kerr spacetime. The adiabatic approximation. Foundations of self-force theory: matched asymptotic expansions. Practical methods: puncture scheme and mode-sum regularization. 

References: 

  1. Leor Barack, Adam Pound, Self-force and radiation reaction in general relativity, arXiv:1805.10385 [gr-qc]. 
 
13:00 to 14:00 - Lunch
15:30 to 16:00 - Tea/coffee break
16:00 to 17:30 Adam Pound (University of Southampton, UK) Course 4 Self-force and radiation reaction in general relativity

Overview of extreme mass ratio inspirals.  Perturbation theory in GR. Orbital dynamics in Schwarzschild and Kerr spacetime. The adiabatic approximation. Foundations of self-force theory: matched asymptotic expansions. Practical methods: puncture scheme and mode-sum regularization. 

References: 

  1. Leor Barack, Adam Pound, Self-force and radiation reaction in general relativity, arXiv:1805.10385 [gr-qc]. 
Wednesday, 24 July 2019
Time Speaker Title Resources
09:30 to 11:00 Luc Blanchet (Institute of Astrophysics, France) Course 3 Gravitational radiation from post-Newtonian sources and inspiralling compact binaries (Lecture 3)

Quadrupole formula, effect of GWs on matter, problem of the generation of GWs; and more advanced ones: post-Newtonian methods, the multipolar post-Minkowskian expansion, problem of motion, applications to compact binary systems, Fokker Lagrangian and Hamiltonian, effects of spins and internal structure.

References: 

  1. L. Blanchet, Living Rev. Relativ. (2014) 17: 2. https://doi.org/10.12942/lrr-2014-2

Preparatory material: 

  1. Kip S. Thorne, "Gravitational Radiation," in Three Hundred Years of Gravitation, ed. S.W. Hawking and W. Israel (Cambridge University Press, 1987), pp. 330-458.
  2. Michele Maggiore, Gravitational Waves: Volume 1: Theory and Experiments (Cambridge University Press)
  3. Misner, Thorne, Wheeler, Gravitation (Princeton University Press) [Chapters 18 (weak gravitational fields), 35 (propagation of GWs), 36 (generation of GWs) and Exercises: 35.1, 35.2, 35.15, 36.2, 36.5, 36.6, 36.8, 36.9]
 
11:00 to 11:30 - Tea/coffee break
11:30 to 13:00 Adam Pound (University of Southampton, UK) Course 4 Self-force and radiation reaction in general relativity (Lecture 3)

Overview of extreme mass ratio inspirals.  Perturbation theory in GR. Orbital dynamics in Schwarzschild and Kerr spacetime. The adiabatic approximation. Foundations of self-force theory: matched asymptotic expansions. Practical methods: puncture scheme and mode-sum regularization. 

References: 

  1. Leor Barack, Adam Pound, Self-force and radiation reaction in general relativity, arXiv:1805.10385 [gr-qc]. 
 
13:00 to 14:00 - Lunch
14:00 to 15:30 Luc Blanchet (Institute of Astrophysics, France) Course 3 Gravitational radiation from post-Newtonian sources and inspiralling compact binaries

Quadrupole formula, effect of GWs on matter, problem of the generation of GWs; and more advanced ones: post-Newtonian methods, the multipolar post-Minkowskian expansion, problem of motion, applications to compact binary systems, Fokker Lagrangian and Hamiltonian, effects of spins and internal structure.

References: 

  1. L. Blanchet, Living Rev. Relativ. (2014) 17: 2. https://doi.org/10.12942/lrr-2014-2
15:30 to 16:00 - Tea/coffee break
16:00 to 17:30 Adam Pound (University of Southampton, UK) Course 4 Self-force and radiation reaction in general relativity

Overview of extreme mass ratio inspirals.  Perturbation theory in GR. Orbital dynamics in Schwarzschild and Kerr spacetime. The adiabatic approximation. Foundations of self-force theory: matched asymptotic expansions. Practical methods: puncture scheme and mode-sum regularization. 

References: 

  1. Leor Barack, Adam Pound, Self-force and radiation reaction in general relativity, arXiv:1805.10385 [gr-qc]. 
Thursday, 25 July 2019
Time Speaker Title Resources
09:30 to 11:00 Luc Blanchet (Institute of Astrophysics, France) Course 3 Gravitational radiation from post-Newtonian sources and inspiralling compact binaries (Lecture 4)

Quadrupole formula, effect of GWs on matter, problem of the generation of GWs; and more advanced ones: post-Newtonian methods, the multipolar post-Minkowskian expansion, problem of motion, applications to compact binary systems, Fokker Lagrangian and Hamiltonian, effects of spins and internal structure.

References: 

  1. L. Blanchet, Living Rev. Relativ. (2014) 17: 2. https://doi.org/10.12942/lrr-2014-2

Preparatory material: 

  1. Kip S. Thorne, "Gravitational Radiation," in Three Hundred Years of Gravitation, ed. S.W. Hawking and W. Israel (Cambridge University Press, 1987), pp. 330-458.
  2. Michele Maggiore, Gravitational Waves: Volume 1: Theory and Experiments (Cambridge University Press)
  3. Misner, Thorne, Wheeler, Gravitation (Princeton University Press) [Chapters 18 (weak gravitational fields), 35 (propagation of GWs), 36 (generation of GWs) and Exercises: 35.1, 35.2, 35.15, 36.2, 36.5, 36.6, 36.8, 36.9]
 
11:00 to 11:30 - Tea/coffee break
11:30 to 13:00 Adam Pound (University of Southampton, UK) Course 4 Self-force and radiation reaction in general relativity (Lecture 4)

Overview of extreme mass ratio inspirals.  Perturbation theory in GR. Orbital dynamics in Schwarzschild and Kerr spacetime. The adiabatic approximation. Foundations of self-force theory: matched asymptotic expansions. Practical methods: puncture scheme and mode-sum regularization. 

References: 

  1. Leor Barack, Adam Pound, Self-force and radiation reaction in general relativity, arXiv:1805.10385 [gr-qc]. 
 
13:00 to 14:00 - Lunch
14:00 to 15:30 Luc Blanchet (Institute of Astrophysics, France) Course 3 Gravitational radiation from post-Newtonian sources and inspiralling compact binaries

Quadrupole formula, effect of GWs on matter, problem of the generation of GWs; and more advanced ones: post-Newtonian methods, the multipolar post-Minkowskian expansion, problem of motion, applications to compact binary systems, Fokker Lagrangian and Hamiltonian, effects of spins and internal structure.

References: 

  1. L. Blanchet, Living Rev. Relativ. (2014) 17: 2. https://doi.org/10.12942/lrr-2014-2

Preparatory material: 

  1. Kip S. Thorne, "Gravitational Radiation," in Three Hundred Years of Gravitation, ed. S.W. Hawking and W. Israel (Cambridge University Press, 1987), pp. 330-458.
  2. Michele Maggiore, Gravitational Waves: Volume 1: Theory and Experiments (Cambridge University Press)
  3. Misner, Thorne, Wheeler, Gravitation (Princeton University Press) [Chapters 18 (weak gravitational fields), 35 (propagation of GWs), 36 (generation of GWs) and Exercises: 35.1, 35.2, 35.15, 36.2, 36.5, 36.6, 36.8, 36.9]

Self-force and radiation reaction in general relativity
15:30 to 16:00 - Tea/coffee break
16:00 to 17:30 Adam Pound (University of Southampton, UK) Course 4 Self-force and radiation reaction in general relativity

Overview of extreme mass ratio inspirals.  Perturbation theory in GR. Orbital dynamics in Schwarzschild and Kerr spacetime. The adiabatic approximation. Foundations of self-force theory: matched asymptotic expansions. Practical methods: puncture scheme and mode-sum regularization. 

References: 

  1. Leor Barack, Adam Pound, Self-force and radiation reaction in general relativity, arXiv:1805.10385 [gr-qc]. 
Friday, 26 July 2019
Time Speaker Title Resources
09:30 to 11:00 Luc Blanchet (Institute of Astrophysics, France) Course 3 Gravitational radiation from post-Newtonian sources and inspiralling compact binaries (Lecture 5)

Quadrupole formula, effect of GWs on matter, problem of the generation of GWs; and more advanced ones: post-Newtonian methods, the multipolar post-Minkowskian expansion, problem of motion, applications to compact binary systems, Fokker Lagrangian and Hamiltonian, effects of spins and internal structure.

References: 

  1. L. Blanchet, Living Rev. Relativ. (2014) 17: 2. https://doi.org/10.12942/lrr-2014-2

Preparatory material: 

  1. Kip S. Thorne, "Gravitational Radiation," in Three Hundred Years of Gravitation, ed. S.W. Hawking and W. Israel (Cambridge University Press, 1987), pp. 330-458.
  2. Michele Maggiore, Gravitational Waves: Volume 1: Theory and Experiments (Cambridge University Press)
  3. Misner, Thorne, Wheeler, Gravitation (Princeton University Press) [Chapters 18 (weak gravitational fields), 35 (propagation of GWs), 36 (generation of GWs) and Exercises: 35.1, 35.2, 35.15, 36.2, 36.5, 36.6, 36.8, 36.9]
 
11:00 to 11:30 - Tea/coffee break
11:30 to 13:00 Adam Pound (University of Southampton, UK) Course 4 Self-force and radiation reaction in general relativity

Overview of extreme mass ratio inspirals.  Perturbation theory in GR. Orbital dynamics in Schwarzschild and Kerr spacetime. The adiabatic approximation. Foundations of self-force theory: matched asymptotic expansions. Practical methods: puncture scheme and mode-sum regularization. 

References: 

  1. Leor Barack, Adam Pound, Self-force and radiation reaction in general relativity, arXiv:1805.10385 [gr-qc]. 
 
13:00 to 14:00 - Lunch
14:00 to 15:30 Adam Pound (University of Southampton, UK) Course 4 Self-force and radiation reaction in general relativity (Lecture 6)

Overview of extreme mass ratio inspirals.  Perturbation theory in GR. Orbital dynamics in Schwarzschild and Kerr spacetime. The adiabatic approximation. Foundations of self-force theory: matched asymptotic expansions. Practical methods: puncture scheme and mode-sum regularization. 

References: 

  1. Leor Barack, Adam Pound, Self-force and radiation reaction in general relativity, arXiv:1805.10385 [gr-qc]. 
 
15:30 to 16:00 - Tea/coffee break