Pedro Fernandes Tavares
(MAX-IV Laboratory)
17/08/2015, 09:00
The electromagnetic radiation produced by accelerated charged particle beams, known as synchrotron light, is a key tool in the characterization of a wide range of matter at the molecular and atomic level. Worldwide about 70 facilities have been built over the past 40 years to produce synchrotron radiation and deliver it to experiments across a wide range of sciences such as physics, chemistry,...
Francesca Curbis
(Max-IV Laboratory)
17/08/2015, 09:45
This course will describe 1) Basic relations (units, kinetic energy, 4-momentum, relativistic particle); 2) Lorentz force & Maxwell’s equations; 3) types of accelerators and electron guns; 4) Oscillating EM fields in linacs; 5) Circular accelerators; 6) Synchrotrons and phase stability; 7) Magnets (dipoles, quadrupoles, sextupoles) and 8) focusing properties [NO equation of motion, NO dynamics].
Francesca Curbis
(Max-IV Laboratory)
17/08/2015, 10:45
This course will describe 1) Basic relations (units, kinetic energy, 4-momentum, relativistic particle); 2) Lorentz force & Maxwell’s equations; 3) types of accelerators and electron guns; 4) Oscillating EM fields in linacs; 5) Circular accelerators; 6) Synchrotrons and phase stability; 7) Magnets (dipoles, quadrupoles, sextupoles) and 8) focusing properties [NO equation of motion, NO dynamics].
Galina Skripka
(Max-IV Laboratory),
Stephen Molloy
(European Spallation Source ESS AB),
Tessa Charles
(Monash University (Australia))
17/08/2015, 14:00
Sverker Werin
(Max-IV Laboratory)
18/08/2015, 08:45
This course will describe general electro-magnetic fields and matrices, phase space, beam transport as basis for accelerator science. It will introduce the function and use of dipole and quadruple magnets Magnets (D, Q) and Radio-frequency cavities.
This course will describe particle motion in magnetic fields, single particle, betatron motion, dispersion, beams, TWISS, Liouville, resonances....
Sverker Werin
(Max-IV Laboratory)
18/08/2015, 10:45
This course will describe general electro-magnetic fields and matrices, phase space, beam transport as basis for accelerator science. It will introduce the function and use of dipole and quadruple magnets Magnets (D, Q) and Radio-frequency cavities.
This course will describe particle motion in magnetic fields, single particle, betatron motion, dispersion, beams, TWISS, Liouville, resonances....
Olivia Karlberg
(Max-IV Laboratory),
Teresia Olsson
(Max-IV Laboratory),
Tessa Charles
(Monash University (Australia))
18/08/2015, 14:00
Anders Karlsson
(Lund University / LTH)
18/08/2015, 16:00
Maja Olvegård
(Uppsala University)
19/08/2015, 08:45
Beam diagnostic instruments are the eyes of the accelerator, the best - or even the only - tools that we have to monitor and control the beam. This lectures will give the basics of "what, where and how" of beam diagnostics.
Different types of accelerators calls for different diagnostic methods. We will discuss the most important beam parameters that generally are monitored, a few common...
Christine Darve
(European Spallation Source ESS AB)
19/08/2015, 10:45
This course will describe the different components and technologies used to operate particle accelerators, from the Radio-Frequency Quadrupole, Drift Tube Linac and supraconducting cavities. We will use the example of the ESS proton accelerator and the LHC machine to support the description of accelerator environment and interfaces (e.g. RF systems, cryogenics, vacuum, water, radiation...
Carlos Martins
(European Spallation Source)
19/08/2015, 11:30
The RF sources are power systems that convert electrical power from a standard electrical power grid into RF microwave power, at the desired frequency and amplitude, in order to excite the RF cavities, which in turn will generate the electrical fields that will accelerate the particle beam.
The related power chain consists of different components which are very specific and unique at a...
Christine Darve
(European Spallation Source ESS AB),
Joel Andersson
(Max-II Laboratory)
19/08/2015, 14:00
Franz Bødker Franz Bødker
(Danfysik)
20/08/2015, 08:45
This course will describe the magnets needed in a particle accelerator. We will start out by looking into the basic functions of a classic electromagnet with magnetic flux generated by a current and guided by a magnetic iron frame. Then we will go into details with the basic functions of the bending dipole such as the required field strength and field quality. This will lead to a description...
Pauli Heikkinen
(Jyväskylä University)
20/08/2015, 10:45
This course will describe: 1) Vacuum: Introduction to basic concepts and units; vacuum regions; residual gas: Maxwell - Boltzmann distribution for energy for residual gas (velocity distribution, average collision distance, molecular layer formation); 2) Basics of vacuum equipment (Pumping speed, conductance, hardware); 3) High voltage use (DC, AC): Forces due to electric and magnetic field...
Anders Karlsson
(Lund University / LTH),
Christine Darve
(European Spallation Source ESS AB),
Maja Olvegård
(Uppsala University),
Yogi Rutambhara
(European Spallation Source)
20/08/2015, 14:00
Sverker Werin
(Lund University)
21/08/2015, 08:45
This course will describe Radiation, electromagnetic fields, relativity, bending magnet radiation, undulators, wigglers, coherence, bandwidth, diffraction, pulse lengths
Lars Præstegaard
(Aarhus University Hospital)
21/08/2015, 10:45
This course will describe 1) Short introduction to the basic theory of waveguides, cavities, and linear accelerators; 2) Rationale for radiation therapy (what is cancer, radiation damage, fractionation, therapeutic window); 3) Electron linacs for radiotherapy (beam optics, how to change the energy, and treatment head design).
Lars Præstegaard
(Aarhus University Hospital)
21/08/2015, 11:45
This seminar will present the following topics:
- Basic theory of the proton cyclotrons (and recap. of proton synchrotrons)
- Medical applications of isotope production
- Rationale for hadron therapy (Bragg peak, dose distribution, skin dose, biological effectiveness).
- Treatment delivery of hadron therapy (gantries, passive scattering, pencil beam scanning, lateral dose penumbra,...
Erik Adli
(Oslo University)
21/08/2015, 14:00
The study the fundamental particles and the forces of nature is the reason particle accelerators were invented about hundred years ago. This field has driven the development of accelerator technology up to today. I will discuss the requirements that particle physics and nuclear physics impose on particle accelerator design, and I will review some of the major discoveries achieved by particle...
Erik Adli
(Oslo University)
21/08/2015, 15:00
The users communities continuously ask for improved accelerator parameters; higher beam energy, better beam brilliance and higher beam power. Clever accelerator physicists have throughout history invented new theory and better technology in order to overcome limitations in particle accelerator performance. In this tutorial we together go through a few of the main limitations of current...
Anders Borgström
(LTH),
Anders Karlsson
(LTH),
Christine Darve
(European Spallation Source ESS AB),
Heikkinen Pauli
23/08/2015, 13:00
