Presentation is loading. Please wait.

Presentation is loading. Please wait.

Chapter 11 Rüdiger Schmidt (CERN) – Darmstadt TU - 2011 –Version E2.2 RF cavities for particle accelerators.

Published byJessica Hood Modified over 8 years ago

Similar presentations

Presentation on theme: "Chapter 11 Rüdiger Schmidt (CERN) – Darmstadt TU - 2011 –Version E2.2 RF cavities for particle accelerators."— Presentation transcript:

1 Chapter 11 Rüdiger Schmidt (CERN) – Darmstadt TU - 2011 –Version E2.2 RF cavities for particle accelerators

2 2 Accelerating structures in linear and circular accelerators Acceleration cavity (cavity) Analogy between oscillating circuit and cavity Cylindrical cavity Shunt impedance and quality factor

3 3 2a Acceleration in the cylindrical cavityT=0 (accelerating phase) z z E0E0 E(z) g (100 MHz)

4 4 Circular accelerator: Acceleration by travelling many times through few RF cavities Linear accelerator: Acceleration by traveling once through many RF Linear and circular accelerators

5 5 Analogy between cavity and oscillating circuit L R A simple RF accelerator would work with a capacitor (with an opening for the beam) and a coil in parallel to the capacitor. The energy oscillates between electric and magnetic field. C L R

6 6 Analogy between cavity and oscillating circuit Oscillating circuit with capacitor, coil and resistance. C L R

7 For a frequency of 100 MHz, a typical value for an accelerator, the inductance of the coil and the capacity of the condenser must be chosen very small. Example:

8 8 From oscillating circuit to the cavity C L C L The fields in the cavity oscillate in TM010 mode (no longitudinal magnetic field). There are an infinite number of oscilllation modes, but only a few are used for cavities (calculation from Maxwells equations, application for waveguides, for example K.Wille)

9 9 Parameter of a cylindrical cavity („pill-box“) A cylindrical cavity with the length of g, the aperture 2*a and the field of E(t) g 2a z

10 10 g 2a Acceleration in a cylindrical cavity z z E0E0 E(z)

11 11 Cavity with rotational symmetry z gcgc The cavity parameter depend on the geometry and the material: Geometry => Frequency Material => Quality factor r0r0 Comes from Besselfunction (Solution of wave equation)

12 12 Field strength for E 010 mode for a „pillbox cavity“ z r0r0

13

14 14 Example for „Transit Time Factor“

15 15 Illustration for the electric field in the RF cavity

16 16 Superconducting RF cavity for Tesla and X-ray laser at DESY RF cavity with 9 cells

17 17 Normal-conducting RF cavity for LEP

18 18 Parameters for Cavities Shunt impedance (Definition for a circular accelerator) : Quality factor Q : For the DORIS Cavity : Q factor: 38000

Download ppt "Chapter 11 Rüdiger Schmidt (CERN) – Darmstadt TU - 2011 –Version E2.2 RF cavities for particle accelerators."

Similar presentations

Introduction to RF for Accelerators

Introduction to RF for Accelerators
Introduction to Radio Frequency Quadrupoles

Introduction to Radio Frequency Quadrupoles
Light Waves and Polarization Xavier Fernando Ryerson Communications Lab

Light Waves and Polarization Xavier Fernando Ryerson Communications Lab
Radio frequency usage/applications Dr S. T. Boogert (accelerator physicist) John Adams Institute at Royal Holloway Royal Holloway.

Radio frequency usage/applications Dr S. T. Boogert (accelerator physicist) John Adams Institute at Royal Holloway Royal Holloway.
Shuichi Noguchi, KEK6-th ILC School, November 20111 Shuichi Noguchi, KEK6-th ILC School, November 20111 RF Basics; Contents  Maxwell’s Equation  Plane.

Shuichi Noguchi, KEK6-th ILC School, November Shuichi Noguchi, KEK6-th ILC School, November RF Basics; Contents  Maxwell’s Equation  Plane.
Course B: rf technology Normal conducting rf Overall Introduction and Part 1: Introduction to rf Walter Wuensch, CERN Seventh International Accelerator.

Course B: rf technology Normal conducting rf Overall Introduction and Part 1: Introduction to rf Walter Wuensch, CERN Seventh International Accelerator.
CHAPTER 5 CROSSED-FIELD TUBES (M-TYPE TUBES)

CHAPTER 5 CROSSED-FIELD TUBES (M-TYPE TUBES)
Part2: Cavities and Structures Modes in resonant cavity From a cavity to an accelerator Examples of structures JUAS 2015 Linacs-JB.Lallement - JUAS 20151.

Part2: Cavities and Structures Modes in resonant cavity From a cavity to an accelerator Examples of structures JUAS 2015 Linacs-JB.Lallement - JUAS
Eric Prebys, FNAL.  We consider motion of particles either through a linear structure or in a circular ring USPAS, Knoxville, TN, Jan. 20-31, 2014 Lecture.

Eric Prebys, FNAL.  We consider motion of particles either through a linear structure or in a circular ring USPAS, Knoxville, TN, Jan , 2014 Lecture.
Sub-Harmonic Buncher design for CLIC Drive Beam Injector Hamed Shaker School of Particles and Accelerators Institute for Research in Fundamental Sciences,

Sub-Harmonic Buncher design for CLIC Drive Beam Injector Hamed Shaker School of Particles and Accelerators Institute for Research in Fundamental Sciences,
1 Basics of Microwave Measurements Steven Anlage

1 Basics of Microwave Measurements Steven Anlage
RF particle acceleration Kyrre N. Sjøbæk * FYS 4550 / FYS 9550 – Experimental high energy physics University of Oslo, 26/9/2013 *k.n.sjobak(at)fys.uio.no.

RF particle acceleration Kyrre N. Sjøbæk * FYS 4550 / FYS 9550 – Experimental high energy physics University of Oslo, 26/9/2013 *k.n.sjobak(at)fys.uio.no.
Microstrip Surface Microstrip Consists of a signal line, the top and sides exposed to air, on the surface of a board of dielectric constant E r and referenced.

Microstrip Surface Microstrip Consists of a signal line, the top and sides exposed to air, on the surface of a board of dielectric constant E r and referenced.
Topic One: Acceleration UW Spring 2008 Accelerator Physics J. J. Bisognano 1 Accelerator Physics Topic I Acceleration Joseph Bisognano Synchrotron Radiation.

Topic One: Acceleration UW Spring 2008 Accelerator Physics J. J. Bisognano 1 Accelerator Physics Topic I Acceleration Joseph Bisognano Synchrotron Radiation.
Transmission Line Theory

Transmission Line Theory
Accelerator Physics with Relativity By Mark, Jack and Frances (Designing the LHC in an hour and a half)

Accelerator Physics with Relativity By Mark, Jack and Frances (Designing the LHC in an hour and a half)
Photocathode 1.5 (1, 3.5) cell superconducting RF gun with electric and magnetic RF focusing Transversal normalized rms emittance (no thermal emittance)

Photocathode 1.5 (1, 3.5) cell superconducting RF gun with electric and magnetic RF focusing Transversal normalized rms emittance (no thermal emittance)
Chapter 30 Inductance. Inductor and Inductance Capacitor: store electric energy Inductor: store magnetic energy Measure how effective it is at trapping.

Chapter 30 Inductance. Inductor and Inductance Capacitor: store electric energy Inductor: store magnetic energy Measure how effective it is at trapping.
RF Cavity Design Part 2/3 Combined slides of

RF Cavity Design Part 2/3 Combined slides of
RF Cavity Design with Superfish

RF Cavity Design with Superfish

Similar presentations

Ads by Google