Short Introduction to CLIC and CTF3, Technologies for ... · frequency multiplication pulse...

Short Introduction to CLIC and CTF3,Technologies for Future Linear Colliders

Explanation of the Basic Principles and GoalsVisit to the CTF3 Installation

Roger Ruber

2Roger Ruber - CLIC/CTF3 Visit - Introduction

Collider History

• hadron collider at the frontier of physics– huge QCD background– not all nucleon energy available

in collision

• lepton collider for precision physics– well defined CM energy– polarization possible

• next machine after LHC– e+e- collider– energy determined by LHC discoveries

consensus Ecm ≥0.5 TeV

Simulation of HIGGS production e+e– → Z H Z → e+e–, H →

Circular versus Linear Collider

Circular Collidermany magnets, few cavities, stored beamhigher energy → stronger magnetic field

→ higher synchrotron radiation losses (∝E4/R)

Linear Colliderfew magnets, many cavities, single pass beamhigher energy → higher accelerating gradient

higher luminosity → higher beam power (high bunch repetition)

source main linac

accelerating cavities

Cost of Circular & Linear Accelerators

Circular Collider• ΔE ~ (E4/m4R)• cost ~ aR + b ΔE• optimization: R~E2 → cost ~ cE2

Linear Collider• E ~ L• cost ~ aL

energy

CircularCollider

LinearCollider

200 GeV e-

e+ Linac

Interaction Point with Detector

e- Linace+ source e- source

RF powerSource

Linear Collider R&D

CTF3 goals:1. high accelerating gradient2. efficient power production3. feasibility demonstration

accelerating cavities accelerating cavities

Acceleration of Charged Particles

• Lorenz (EM) force most practical

• increasing particle energy

• to gain 1 MeV energy requires a 1 MV field

Direct-voltage acceleration used in• TV tube: 20~40 kV• X-ray tube: ~100 kV• tandem van de Graaff: up to ~25 MV

)( EBvF +×= e

eUdeE =⋅=Δ ∫ rE +-

Drift Tube Linac: Higher Integrated Field

Courtesy E. Jensen © C

• electrons β~1(v~c)

• short pulses• high frequency

>3 GHz

• typical10~20 MV/m

• CLIC:– 12 GHz– 240 ns– 100 MV/m

Travelling Wave Structure

RF powersource

electric fieldd

particle bunch

RFload

Accelerating Cavities

CERN PS 19 MHz Cavity (prototype 1966)CLIC 30 GHz Cavity(prototype 2006)

ILC 1.3 GHz Cavity (prototype 2005) © K

Surfing: or How to Accelerate Particles

DC Accelerator RF Accelerator

synchronize particlewith an

electromagnetic wave!

e+ Linac

RF powerSource

Linear Collider R&D

Challenges:1. high accelerating gradient2. efficient power production3. feasibility demonstration

Electromagnetic Waves

• static electron→ electric field

• moving electron→ electromagnetic wave

• constant electron beam→ static electric field

+ static magnetic field

• bunched electron beam→ electromagnetic wave

CLIC Two-beam Acceleration Concept

• 12 GHz modulated andhigh power drive beam

• RF power extractionin a special structure(PETS)

• use RF power toaccelerate main beam

Drive Beam Acceleratorefficient acceleration in fully loaded linac

Power Extraction

Drive Beam Decelerator Sector

Combiner Ring x 3

Combiner Ring x 4

pulse compression & frequency multiplication

Delay Loop x 2gap creation, pulse

compression & frequency multiplication

RF TransverseDeflectors

Recombination to Increase Peak Power & Frequency

140 µs train length - 24 x 24 sub-pulses - 4.2 A2.4 GeV - 60 cm between bunches

240 ns

24 pulses – 100 A – 2.5 cm between bunches

240 ns5.8 µs

Drive beam time structure - initial Drive beam time structure - final

Drive Beam Generation Scheme

e+ Linac

RF powerSource

Linear Collider R&D

Challenges:1. high accelerating gradient2. efficient power production3. feasibility demonstration

CLIC: Compact Linear Collider

Main LinacC.M. Energy 3 TeV

Peak luminosity 2x1034 cm-2s-1

Beam Rep. rate 50 Hz

Pulse time duration 156 ns

Average field gradient 100 MV/m

# accelerating cavities 2 x 71,548 Φ4.5m tunnel

CTF3 Test Facility

• demonstration drive beam generation• evaluate beam stability & losses in deceleration• develop power production & accelerating structures

X 5 Combiner Ring

X 2Delay loop

42 mDrive BeamInjector

180 MeV Probe Beam Injector

Two-Beam Test-stand

Drive Beam Accelerator

30 A - 150 MeV140 ns

30 GHz High Gradient Test stand

Decelerator Test Beam LineDrive beam stability bench marking

CLIC sub-unit

Drive beam generation scheme

Short Introduction to CLIC and CTF3, Technologies for ... · frequency multiplication pulse...

Documents

High-power multimode X-band rf pulse compression system

Radar pulse compression using stepped Frequency train of pulses

A Pulse Compression Waveform for Improved …boonleng/pdf/kurdzo++14_waveform.pdfA Pulse Compression Waveform for Improved-Sensitivity Weather Radar Observations ... work in order

STUDY OF RADAR PULSE COMPRESSION - NASA · 2013-08-31 · nasa contractor report nasa cr-137474 study of radar pulse compression (nasa-cr-137474) study of radar pulse n751401-3 iconpression

RF Pulse Compression Stabilization at the CTF3 CLIC Test

Trade Off Analysis of Pulse Compression for a Satellite

Multifunction Phased Array Radar Pulse Compression Limits

A Pulse Compression Waveform for Improved-Sensitivity

pulse compression miit

Pulse compression with planar hollow waveguides: a pathway

Pulse Compression of Short Wave Infrared Optical

Shear wave pulse compression for dynamic elastography using phase- sensitive … · Shear wave pulse compression for dynamic elastography using phase-sensitive optical coherence tomography

Linear Frequency Modulation Pulse Compression Technique · PDF file1 Linear Frequency Modulation Pulse Compression Technique on Generic Signal Model Uttam K. Majumder ABSTRACT This

Radar 2009 a 11 waveforms and pulse compression

Phase-Coded Pulse Compression - Festo

for ELECTRON BEAM PULSE COMPRESSION-BASED PHYSICS

Pulse Compression Radar

Investigation in Pulse Compression Techniques for radar

Development of Radar Pulse Compression …ethesis.nitrkl.ac.in/3027/1/Thesis.pdf · This is to certify that the thesis entitled “Development of Radar Pulse Compression Techniques

Analysis of cooperative jamming against pulse compression