Did you know that particle accelerators play an important role in many functions of todays society and that there are over 30 000 accelerators in operation worldwide? A few examples are accelerators for radiotherapy which are the largest application of accelerators, altogether with more than 11000 accelerators worldwide. These accelerators range from very compact electron linear accelerators with a length of only about 1 m to large carbon ion synchrotrons with a circumference of more than 50 m and a huge rotating carbon ion gantry with a weight of 600 tons!
There are also a growing number of synchrotron light sources in the world. The light in these sources are created by electrons that are accelerated to almost the speed of light. This light can reveal the molecular structures of materials and also take x-ray pictures of the inner structure of objects. Synchrotron light sources are very important in life sciences, material sciences and chemistry. Another type of accelerators are used in spallation sources, like the European Spallation Source in Lund, Sweden. Here protons are accelerated to very large energies. They produce neutrons when they are smashed into a disc of tungsten. These neutrons are used for finding the inner structure of objects and atomic structures of materials. Finally there are many accelerators for basic physics, like the large hadron collider in Cern.
This course takes you on a journey through the technologies used in particle accelerators: The microwave system which produce the electromagnetic waves that accelerate particles; The magnet technology for the magnets that guide and focus the beam of particles; The monitoring systems that determine the quality of the beam of particles; Finally the vacuum systems that create ultra high vacuum so that the accelerated particles do not collide with molecules and atoms. Exciting right!
The course is graded through quizzes, one for each of the four modules. Throughout the course there are also a number of training quizzes to offer you support. The four modules in the course are: RF-systems, Magnet technology, Beam diagnostics, and Vacuum techniques. In total there are 48 lectures, where each lecture is a 2-4 minutes long video presentation. Some of the lectures are followed by short texts with complementary information and all will hopefully be an exciting collection for you to engage with.
Have fun!
Fundamentals of particle accelerator technology (NPAP MOOC)
von
Lund University
Über diesen Kurs
Was Sie lernen werden
You will learn the basic technology of particle accelerators.
You will understand the basic principles for how particles are accelerated, and how they can be guided.
You will learn about different ways to monitor the beam.
You will learn about vacuum: Why we need vacuum in accelerators; Where particles that give rise to pressure comes from; How one create vacuum
Lehrplan - Was Sie in diesem Kurs lernen werden
Woche
14 Stunden zum Abschließen
RF-systems
This module is an introduction to the RF systems of particle accelerators. RF stand for radio frequency and indicates that the systems deal with electromagnetic waves with frequencies that are common for radio systems. The RF system generates electromagnetic waves and guides them down to cavities. The cavities are located along the beam pipe such that the particles pass through the cavities when they travel along the accelerator. When the waves enter the cavity they create as standing wave inside the cavity. it is the electric field of this standing wave that accelerates the particles. In the module we describe the amplifier, which generates and amplifies the electromagnetic waves. We describe different types of waveguides which transport the waves from the amplifier to the cavity. We also describe the most common types of cavities. Most of the system is described without equations but in the texts following the lectures you will find some of the theory for the RF-system.
14 Videos (Gesamt 36 min), 10 Lektüren, 15 Quiz
14 Videos
Outline of the RF-system1m
Pill-box cavities5m
Energy3m
Coaxial waveguides2m
Rectangular waveguides2m
Computer simulations2m
The circulator1m
Introduction to RF-amplifiers2m
The klystron4m
General properties2m
Drift tube linac (DTL)1m
Elliptical cavity1m
Traveling wave cavity2m
10 Lektüren
Introduction10m
Basic concepts 110m
A mathematical description of the pillbox cavity10m
A mathematical description of energy in cavities10m
A mathematical description of the coaxial waveguide10m
A mathematical description of rectangular waveguides10m
More on the circulator10m
Gain of amplifiers10m
Drift tube Linac: example10m
Elliptical cavity: example10m
15 praktische Übungen
Quiz Introduction6m
Outline of RF-system6m
Pill-box cavities10m
Energy6m
Coaxial waveguides6m
Rectangular waveguides2m
Computer simulations4m
Circulator4m
Introduction to amplifiers6m
The klystron8m
General properties6m
Drift tube linac4m
Elliptical cavities6m
Traveling wave cavity4m
RF-systems: Graded test30m
Woche
21 Stunde zum Abschließen
Magnet technology for accelerators
This module is about the types of magnets that are used in particle accelerators. It introduces dipole magnets, quadrupole magnets, sextupole magnets and octupole magnets, and describe where these are needed and how they are designed. In the most common types of magnets, the magnetic field are produced by currents running in normal conducting wires. When large magnetic fields are required one use superconducting magnets and the module describe how these are designed. There are also cases when quite weakl magnetic fields are required and then one can use permanent magnets. This a green alternative since they have zero power consumption. The permanent magnets are also covered in this module.
4 Videos (Gesamt 27 min), 1 Lektüre, 5 Quiz
4 Videos
Fast ramp magnets4m
Superconducting magnets6m
Permanent accelerator magnets and insertion devices6m
1 Lektüre
Magnetic circuits10m
5 praktische Übungen
Basic concepts18m
Fast ramped magnets10m
Superconducting magnets6m
Permanent magnets and insertion devices6m
Magnet technology: Graded test
Woche
33 Stunden zum Abschließen
Beam Diagnostics
In this module we describe how we can measure and monitor various beam parameters in a particle accelerator. We introduce a few examples of common instruments for each specific parameter, starting with beam intensity and beam position, followed by transverse distribution and beam emittance. We also present ways to monitor the longitudinal and the energy distribution. The last section describe how we can determine the amount of particles that the beam loose as it travels through the accelerator.
19 Videos (Gesamt 45 min), 3 Lektüren, 20 Quiz
19 Videos
Important concepts in beam diagnostics3m
Describing the beam2m
Faraday cup2m
Wall current monitor2m
Beam Current Transformer1m
Button pick-up1m
Cavity BPM1m
OTR and Scintillating screens5m
Wire scanner and SEM grid3m
Synchrotron radiation monitor1m
An introduction to longitudinal profile50
Transversely deflecting cavity2m
Streak camera2m
Energy (profile) monitoring: Spectrometer and ToF2m
Energy along a single bunch1m
Introduction to beam loss and machine protection.3m
Ionization chamber2m
Scintillation counter1m
3 Lektüren
Introduction to lecture on current and position measurements10m
Introduction to lecture on transverse beam profile measurements10m
To measure the beam emittance and the Twiss parameters:30m
20 praktische Übungen
Motivation to beam diagnostics2m
Important concepts in beam diagnostics12m
Describing the beam6m
Faraday cup6m
Wall current monitor4m
Beam current transformer4m
Button pick up6m
Cavity BPM4m
OTR and scintillation screens4m
Wire scanner and SEM grid6m
Synchrotron radiation measurement4m
Emittance measurements
Transversely deflecting cavity2m
Streak camera2m
Energy monitoring: Spectrometer and ToF4m
Energy along a single bunch2m
Introduction to beam loss and machine protection2m
Ionization chamber2m
Scintillation counter2m
Beam diagnostics: Graded test
Woche
41 Stunde zum Abschließen
Basics of Vacuum techniques
This module gives an introduction to basic concepts of vacuum physics and techniques in accelerators. Vacuum regions and the behavior of residual gas in these regions are described. Important phenomena, such as velocity distribution, average collision distance and molecular formation are explained by Maxwell-Boltzmann theory. These phenomena are used to determine vacuum criteria for accelerator systems. Basic concepts of vacuum pumps will be described, and different types of vacuum equipment will be presented.
The objective is that the students would understand the behavior of residual gas in Vacuum systems. They should be able to determine Vacuum criteria for a given system. They should also be able to choose proper equipment for Vacuum generation and measurement.
11 Videos (Gesamt 26 min), 1 Lektüre, 11 Quiz
11 Videos
Introduction to pressure/vacuum2m
Three states of residual gas58
Definition of vacuum regions1m
Composition of residual gas1m
Introduction to pumps59
Gas-Displacement Pumps2m
Kinetic Vacuum Pumps2m
Gas-Binding Pumps4m
Vacuum Gauges3m
Vacuum components3m
1 Lektüre
Brief introduction to Maxwell-Boltzmann theory for ideal gas10m
11 praktische Übungen
Motivation4m
Introduction to pressure/vacuum2m
Three states of residual gases8m
Definition of vacuum regions2m
Composition of residual gases
Gas displacement pumps
Kinetic vacuum pumps
Gas binding pump
Vacuum Gauges
Vacuum components
Vacuum technology: Graded test
Woche
510 Minuten zum Abschließen
You have now successfully finalized the course!
1 Lektüre
1 Lektüre
Tillfällig kopia av MOOC 3 outro10m
Dozenten
Anders Karlsson
Professor Electromagnetic TheoryDepartment of Electrical and Information Technology
Pauli Heikkinen
PhD, Chief engineer for the Accelerator Laboratory at the University of Jyväskylää in Finland
Franz Bødker
R&D Engineer, Ph.D.Technical University of Denmark
Maja Olvegård
Post Doc in Beam DiagnosticsDepartment of Physics and Astronomy, FREIA, Uppsala University
Über Lund University
Lund University was founded in 1666 and has for a number of years been ranked among the world’s top 100 universities. The University has 47 700 students and 7 500 staff based in Lund, Sweden. Lund University unites tradition with a modern, dynamic, and highly international profile. With eight different faculties and numerous research centres and specialized institutes, Lund is the strongest research university in Sweden and one of Scandinavia's largest institutions for education and research. The university annually attracts a large number of international students and offers a wide range of courses and programmes taught in English.
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