Simulations and tests for PIPERADE
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Simulations and tests for PIPERADE Simulations and tests for PIPERADE P. Ascher, K. Blaum, M. Heck, S. Naimi Piperade Meeting, 27 th -28 th May 2013, Bordeaux
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Simulations and tests for PIPERADE. P. Ascher, K. Blaum, M. Heck, S. Naimi. Piperade Meeting, 27 th -28 th May 2013, Bordeaux. SIMCO excitation: Introduction. M. Rosenbusch et al, Int. J. M. Spec., 325-327, 51-57 (2012) M. Kretzchmar, Int. J. M. Spec., 325-327, 30-44 (2012). - PowerPoint PPT Presentation
Transcript of Simulations and tests for PIPERADE
Simulations and tests for PIPERADESimulations and tests for PIPERADE
P. Ascher, K. Blaum, M. Heck, S. Naimi
Piperade Meeting, 27th-28th May 2013, Bordeaux
SImultaneous Magnetron and resonant COnversion
- Dipolar excitation at the magnetron frequency -
- Quadrupolar excitation at (+ +- ) for the conversion of the radial modes
M. Rosenbusch et al, Int. J. M. Spec., 325-327, 51-57 (2012)
M. Kretzchmar, Int. J. M. Spec., 325-327, 30-44 (2012)
One SIMCO conversion
Allows to center the ions selectively without buffer gas -> prevents charge-exchange reactions and damping of the motion that decreases
mass resolving power
R+
R-
SIMCO excitation: Introduction
SIMCO excitation
Advantages of SIMCO
No Buffer gas
Mass independent (like BG)
Same selectivity as a quadrupole excitation (same resolution for a given time)
BUT for BG cooling a magnetron exc and a cooling time afterwards are needed!
→ SIMCO is faster (for a given time, SIMCO has a higher resolving power)
Contaminants are brought further compared to the ions of interest, the contaminants can even leave the trap (depends on the magnetron exc parameters…)
SIMCO excitation vs BG Cooling
SIMCO Exc during 60ms
Mag Exc during 4 ms + Quad Exc during 60ms + Cooling time of 100 msP=1e-4 mbar
Time (ms) Time (ms)
R+, R
- (m
m)
R (m
m)
R+, R
- (m
m)
R (m
m)
Time (ms) Time (ms)
2 ions species: 136Te, 136Sb
SIMCO excitation vs BG Cooling
SIMCO Exc during 60ms
Mag Exc during 4 ms + Quad Exc during 60ms + Cooling time of 100 msP=1e-4 mbar
Time (ms) Time (ms)
Time (ms) Time (ms)
R+, R
- (m
m)
R+, R
- (m
m)
R (m
m)
R (m
m)
SIMCO excitation
What is tricky with SIMCO…
One conversion is needed (exactly), time excitation is crucial!
Ions probe radial anharmonicities of the E/B fields during the exc (like BG)
No Buffer gas
Initial conditions crucial! (in particular radial dispersion)
this is not a cooling method, the conditions at the end will not be better than before
During the excitation, the ions probe radial anharmonicities of the trap (B field inhomogeneities)
B2=5.6 (corresponding to an homogeneity of 10 ppm over 5 mm)
B2=0.3 (corresponding to an homogeneity of 5ppm over 5 mm) -> WITCH Magnet (Oxford)
Time (ms) Time (ms)
Time (ms) Time (ms)
R (m
m)
R (m
m)
R (m
m)
R (m
m)
B2=5.6 (corresponding to an homogeneity of 10 ppm over 5 mm)
R (m
m)
R (m
m)
Time (ms) Time (ms)
SIMCO excitation
What is tricky with SIMCO…
One conversion is needed (exactly), time excitation is crucial!
Ions probe radial anharmonicities of the E/B fields during the exc (like BG)
No Buffer gas
Initial conditions crucial! (in particular radial dispersion)
this is not a cooling method, the conditions at the end will not be better than before
Inittial conditions are crucial!
Radial dispersion
But if they are all off-centered this is ok because we can change the phase…
R (m
m)
R (m
m)
R (m
m)
R0 = 1 mm R0 = 2 mm
R0 = 3 mm
Time (ms)
Time (ms) Time (ms)
SIMCO excitation: Simulations
Initial magnetron motion?
R+(t), R-(t)
mag.motion - mag.exc
= -/2 = 0
SIMCO excitation during 15 ms
R+(t), R-(t)
R+(t), R-(t)
Initial conditions Z direction
B2=0.3 (corresponding to 10 ppm over 3 cm) B2=3 (correspondingto 100 ppm over 3 cm)
z= 30 mm
R (m
m)
R (m
m)
Time (ms) Time (ms)
Increasing the number of ions… the main problem is the shielding effect
Initial conditions (x, y, z) = (0.5 mm, 0.5 mm, 15 mm)
512 ions Scaling factor of 2: ~ 1000 contaminants
2 ions of interest
Initial conditions (x, y, z) = (0.5 mm, 0.5 mm, 2 mm)
R (m
m)
R (m
m)
Time (ms) Time (ms)
Time (ms) Time (ms)
R+, R
- (m
m)
R+, R
- (m
m)
Tests at MPIK
Quadrupolar excitation
SIMCO excitation
0 100000 200000 300000 400000 500000 600000
0
100
200
300
400
500
600
700
800
Dip
ola
r si
gn
al
Nb cycles
0 100000 200000 300000 400000 500000 6000000
50
100
150
200
250
DIp
o;ar
sig
na;
NB cycles
Time (ms)
R+, R
- (m
m)
R+, R
- (m
m)
Time (ms)
Tests with MCP detection
An aperture was installed after the trap in order to see a count-rate resonance, but it was not possible to shoot through the aperture
-> Initial magnetron motion too high….
A phosphore screen detector was installed
-> Beam not aligned
What is crucial to improve: the tilted magnetic field and the injection in the trap:
Magnetic field:
An engineer from BRUKER will come in the next weeks to shim again the magnet
Injection: the RFQ is designed and built, still electronics has to be developed…
SIMION simulations of the RFQ in progress
Tests @ MPIK
SIMCO tests in the preparation trap:
- We need to use the RFQ to have good conditions
- No vacuum possible if we use the RFQ
FIrst tests of SIMCO will be done in the measurement trap:
No aperture after the second trap but position-sensitive detector (even better!)
First of all is to look at the beam spot position depending on the excitation time
and at the same time the TOF as a function of the exc time
The method will be investigated up to 100 ions (very high number of ions for SHIPTRAP)
Tests @ SHIPTRAP/GSI
