Argonne National Laboratory Operated by The University of Chicago for the U.S. Department of Energy Applications of psec TOF in proton and heavy-ion accelerators

Argonne National LaboratoryOperated by The University of Chicagofor the U.S. Department of Energy Office of Science

U.S. Department of Energy

Applications of psec TOF in proton and heavy-ion accelerators

Peter OstroumovPico-Sec Timing Hardware Workshop

November 18, 2005

2PioneeringScience andTechnology Pico-Sec Timing Hardware Workshop, November 18, 2005

Outline

● TOF measurements in accelerators RareIsotopeAcceleratorFacility Acceleratedbunchedbeamvelocity(energy)measurements

basedoninducedrfsignals Bunchtimeprofilemeasurementswithresolution~10

picosecondsbasedonstreakcamera

● Improvement of time resolution of the existing BLD

● Bunch time structure measurements using X-rays Highresolutionisobtainedbyusingstreakcameras

● Examples of TOF technique application in nuclear physics experiments at ATLAS: mass and nuclear charge identification of radioactive ions using gas-filled magnet


TOF systems

● High-power (hundreds of kilowatts) accelerators such as RIA driver linac Requirehigh-precisioncontrolofbeamenergy Maintainshortbunches(~40-100picoseconds)

● Beams of rare isotopes must be analyzed by detecting individual particles. Fast time measurements (~20 picoseconds resolution) are necessary to control bunched beam quality

● Absolute energy measurements based on TOF system Requiredformanyexperiments Non-destructive,cheapcomparedtomagnet Wellsuitedforbeamvelocities<0.5c Veryhighaccuracycanbeobtained Widerangeofbeamcurrentsstartingfrom~0.3nA(~1010

particles/sec)canbeanalyzed


Absolute energy measurement using resonant TOF system

48.505 MHz

Beam frequency = 48.500 MHzResonator frequency =48.500 MHz

FEE

Phase meter

f=48.505-48.500 = 5 kHz

FEE FEE



1 1 0 10 0 1

2 2 0 20 0 2

1/ 22 210 1

1 21 2 5 5

0

cos(( ) ) cos( )

cos(( ) ) cos( )

2 cos( )

52

482

rf beam b

rf beam b

b

b b kHz kHz

U U t U t

U U t U t

E A B AB t

kHz

MHz

0 2000 4000 6000 8000 1 104

1.5

1

0.5

0

0.5

1

1.51.3

1.3

E TV( )

1 1040 TV

0 2000 4000 6000 8000 1 104

0.4

0.2

0

0.2

0.40.5

0.5

EE TV( )

1 1040 TV

0 10 20 30 401

0.5

0

0.5

11

1

E1 TV( )

400 TV



● Precision of TOF measurements: Signal–noiseratio Phasejitterduetovibration,somethermaleffects Majorcontribution–beamphasejitter

Phaseadvanceover9m–5400degof48.5MHz

Phasemeterprecision~0.2deg

TOF=300nsec

5

5 5

0.23.7 10

5400

3 10 3.7 10 10 picoseconds

t

t

t

● Accuracy of beam energy measurements:

Additionaleffectisthedistancebetweenthedetectors

TypicalnumberisE/E=210-4


High accuracy is achieved by using

● Chain of bunches, signal is integrated in the resonator (msec);

● Mixing of two frequencies in the resonator helps to avoid extra noise that can be accumulated in external circuits

● The bunch phase at 48.5 MHz is directly translated to 5 kHz and minimizes phase meter errors

● Front End Electronics Amplitudedetection Narrowband-passfilter(5kHz) AGC(automaticgaincontrol)amplifier


Bunch Length detector

1-tangstin target wire, 2-collimator, 3-plates of the rf deflector, 4-MCP, 5-phosphor screen, 6-CCD camera,.

I()

Ion beam

, Z

Utarg Secondary electrons

I(X) X

1 2 3

)sin( tn2

UVV mstfoc

)sin( tn2

UVV mstfoc


Electron beam trajectories with no RF applied (streak camera)

Target wire Electron beam trajectories

Collimator

Deflector plates

Potential contoursb)

a)


Electron beam image on the phosphor with no RF applied

20 mm

100 200 300 400 500

0

5

10

15

20

25

intensity,rel.units

pixels

FocusedelectronbeamprofileResolutionis~15pixelsBunchwidth=10degat97MHz=290picoseconds15pixelscorrespondsto~10picosecondsresolution


RF on, bunch image


Bunch time profile

● 58 Ni bunch profile (a) inferred from scintillator signal (b).


Time resolution

● The time required for the emission of secondary electrons

● The time difference, due to the different arrival times of the secondary electrons originating from different points of the wire, at the rf deflector

● The contribution to the detector resolution from the angular and energy distributions of the secondary electrons

● The time of flight of the electrons through the electrostatic field of the plates.

● Finally the RF voltage and rf phase jitter is a very important factor in determining the time resolution of the detector.


Improvement of time resolution of the existing BLD

● Reduce both the entrance and exit slits size down to ~0.2 mm;

● Use single electron mode of measurements. In the single electron mode the problem associated with the finite size of the SE beam will be minimized.

● Reduce the diameter of the wire to ~0.03 mm;

● Increase the voltage applied to the wire up to 15 kV;

● Increase the rf voltage to have large sweeping amplitude on the exit slit;

● Improve electron beam optics to obtain more isochronous trajectories;

● Improve phase jitter of the rf deflector by introducing an external RF synthesized signal generator with a high stability.


Heavy-ion bunch time structure using X-rays

Streak camera

Focusingspectrographforpicosecondtimeresolutionofionbeam(adaptedfrom[1])

[1]O.N.Rosmejetal. 30th EPS Conference on Contr. Fusion and Plasma Phys., St. Petersburg, 7-11 July 2003 ECA Vol. 27A, O-1.9C


Typical streak camera being used at electron synchrotronsTime resolution of streak cameras can be less than 1 picosecond


Heavy-ion bunch time structure using X-rays (proposal)

● Ions penetrate the thin target ( 0.1-0.2 mm) and undergo multiple collisions with target atoms.

● Excitation of bound electrons followed by radiative decay gives rise to projectile and target radiation. Decay time ~10 femtosec

● Focusing specrograph with spatial resolution provides high spectral and spatial resolution of the K-shell spectra.

● Streak camera measures the temporal structure of the beam with picosecond resolution.


ATLAS Layout


Mass and nuclear charge identification using gas-filled spectrograph

01

, ,

vC Zv

mvB

q

q Z e

C are parameters

Difficulty:a) The masses are very closeb) The same q/m, velocity


TOF for mass and charge identification


Time-of-Flight Measurement with the Storage Ring in the Isochronous Mode (Milan Matos’ presentation)

In jectionIn jectionIn jection

time[ s]

U[V ]

0 1 2

0

-0.5

time[ s]

U[V ]

0 1 2

0

-0.5


Time-of-Flight Spectrum

0

100

200

300

400

500

600

700

496 498 500 502 504 506 508 510 512 514Revolutiontime[ns]

Intensity

103Zr39+

0

5

10

15

20

25

30

35

507.6 507.7 507.8 507.9 508 508.1 508.2

135Te

51+

90Se

34+

127Cd

48+

82Ga

31+

119Rh

45+

111Tc

42+

103Y39+

111Mo

42+

90Br

34+

127In

48+

119Pd

45+

37Si14+

Intensity

revolutiontime[ns]

red-nuclidewithunknownmassblue-nuclidewithknownmass


Conclusion

● Time resolution of 3-5 picoseconds is required to tune and operate high-power heavy-ion linacs

● So far the technique remains complex and expensive to provide high resolution

● TOF is a common technique for identification of mass and nuclear charge of rare isotopes. Currently several large facilities are being constructed worldwide to produce beams of exotic nuclei.

● High resolution MCPs can help to reduce the cost of storage rings or spectrographs in future rare isotope accelerator facilities

Documents

Argonne National Laboratory Operated by The University of Chicago for the U.S. Department of Energy Applications of psec TOF in proton and heavy-ion accelerators