peter müller - solvay institutesmot to mot transfer 13 mot1 mot2 • reduce background from...
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![Page 1: Peter Müller - Solvay InstitutesMOT to MOT transfer 13 MOT1 MOT2 • Reduce background from un-trapped 6He through diff. pumping • Separate MOT functions capture vs. detection •](https://reader036.vdocuments.us/reader036/viewer/2022071408/610113b930222a2b0f209b0b/html5/thumbnails/1.jpg)
Lil’ a with laser trapped 6He
Peter Müller
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6He Collaboration
2
P. Mueller, A. Leredde, T.P. O’Connor, K. Bailey Physics Division, Argonne National Laboratory
A. Garcia, M. Sternberg, F. Wauters, D. Zumwalt, R. Hong,
Y. Bagdasarova, D. Storm, H.E. Svanson, G. Harper CENPA, University of Washington
X. Flechard, E. Liennard
LPC Caen
O. Naviliat-Cuncic NSCL, Michigan State University
PhD, Postdoc
$ PM DOE Early Career Research Grant, DOE CENPA, LPC $
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Weak Interaction Studies: b-n Angular Correlations
6He
6Li
t1/2=0.808 sec
100% b
0+
1+
Qb=3.510 MeV
-1.0
-0.5
0.0
0.5
1.0
Co
rre
latio
n C
oe
f. a
1.00.80.60.40.20.0
T
A
V
S
-50
-40
-30
-20
-10
0
10
20
a(e
xp
) - a
(SM
)
x1
0-3
1.00.80.60.40.20.0
Fermi fraction
6He n
21Na
32Ar
38mK
21Na
Atom Trap Ion Trap
b
bn
b
b
bnb E
mb
E
paEN )cos(1),(
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4
The Case for 6He
β- decay, pure Gamow-Teller decay to g.s. 6Li
Suitable half-life and Q-value
Produced and transferred with high yield (noble gas)
Simple nuclear and atomic structure
Small branch of ~10-6 for 6He → α+d
Current experiments searching for tensor cpl. in b decay
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Beta-Decay Study with Laser Trapped 6He
Recoil time-of-flight spectrum
(MC simulation)
• ~5x109 6He/s production yield • trapping rate ~1x103 6He/s
• ~0.1% statistics in ~8 weeks beam time
Atom trap properties • Highly selective capture • No RF fields or space charge • Low temperature sample (<mK) • Tight spatial confinement (< 100mm)
250 300 350 400 450
a = -1/3
Co
un
ts
Time of Flight, ns
a = +1/3
b-Detector
Trapped 6He
6Li recoil ion detector
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Production of 6He @ CENPA
6He produced using the 7Li(d,3He)6He reaction on molten lithium
Deuteron currents up to 10 μA @ 18 MeV using tandem Van de Graaff accelerator at CENPA/UW
6He extracted to vacuum and transported to low background environment
collimator
cooling
electrical
isolation
lithium cup
heating
temperature
sensor
beam current
measurements
David Zumwalt
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6He Production and Transfer
7
A. Knecht et al., NIM A 660, 43 (2011)
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Precision 6He Lifetime
8
6He decay curve
6He half-life
ft-value
Compare with ab-initio calculations of |MGT| to obtain gA in nuclear medium
A. Knecht et al., PRL 108, 122502 (2012) A. Knecht et al., PRC 86, 035506 (2012)
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Atomic Energy Levels of Helium
2 3S1
1 1S0
389 nm
IS: 43 GHz
1083 nm
IS: 30GHz
2 3P0,1,2
19.8 eV,
e-collision in discharge
3 3P0,1,2
He discharge
metastable
He energy level diagram
3 3S1
706 nm
IS: 600 MHz
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10
Atom Trapping of 6He
Atom Trap Setup
706 nm
1083 nm
@ source 5x109 s-1
Capt. efficiency = 2x10-7
@ trap 1000 s-1
6He Rates
Image
706 nm
23S1
11S0
2 3P2
3 3S1
Trap
1083 nm
He level scheme
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Helium MOT
Setup @ CENPA
11
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MOT Imaging
12
• On-line MOT imaging
• 2 cameras for x/y/z control
• Trap diameter < 200 mm
• Trap stability < 10 mm *
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MOT to MOT transfer
13
MOT1 MOT2
• Reduce background from un-trapped 6He through diff. pumping
• Separate MOT functions capture vs. detection
• Optical “push” beam
• Transverse cooling
• ~40% transfer in 15 ms
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14
Beta and Recoil Ion Detectors
MCP
2 kV/cm
electrode structure
Atom cloud
Beryllium window
Proportional counter
Scintillator
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Beta Detector System
15
Ran Hong
125 mm thick
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Electrode System
16
• Deflect recoil ions (1.4 keV max.) onto 8 cm dia. MCP
• Variable, uniform electric field with 0.05%
relative stability and accuracy
• 1.5 – 2.0 kV/cm -> 80 – 99% coll. eff.
Yelena Bagdasarova
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Electrode, MCP and HV Supply
17
• Stacked HV supplies • Control each electrode separately • Enable variable field geometries
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Recoil Ion Detector
18
Xavier Flechard, Etienne Liennard
MCPs (micro channel plates)
Delay line anodes
On test flange with calibration mask
Digital readout of signals, FPGA processing (LPC FASTER DAQ system)
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Recoil Ion Detector
19
Position calibration with mask, Na+ beam
• DAQ system for beta and recoil detectors works
• MCP efficiency 52 % (70%) • MCP uniformity 95.5 – 99.8% • Timing resolution ~100 ps • Position resolution ~100 mm • Position reconstruction ~ 1 mm
Need to do • In situ calibration with 6He BG • Timing calibration with 4He
Photo-ions (337 nm pulsed N2 laser)
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4He trap diagnostics with MCP
20
He* + X -> He + X+ + e-
He* + He* -> He + He+ + e-
t (ms)
ms
dtx (ns)
dt y
(ns)
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MCP Image of Trapped 6He
21
dtx (ns)
dt y
(ns)
8 cm MCP diameter
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Results: First coincidences
DAMOP | Madison, WI | 06/05/2014
22
• 75 6He/s in MOT 2
• ~0.15 Hz trapped 6He
• ~0.15 Hz background (untrapped 6He)
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Systematic Uncertainties
23
• Detailed MC simulation • Geant4 for beta tracking and detector response • COMSOL for E-field calculation, recoil ion tracking
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Outlook
Short term
Install recirculating discharge source and guide beam
Aim for initial ~1% statistics (300k coincidences)
– 1 Hz coincidence rate, ~ 1 week
Compare with numerical simulations
Medium term
Upgrade trap / detector
– Improve discharge, recirculation, trap and transfer efficiency
– Multilayer MWPC for tracking
High statistics (0.1%) runs
– 10 Hz coincidence rate, ~ 8 weeks
Longer term
- Lil’ b at 10-3: beta spectrometer (PxR, CRES, traps, …)
- Lil’ a at 10-4: shake-off electrons, dipole traps, large MCPs, …
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6He Collaboration
25
P. Mueller, A. Leredde, T.P. O’Connor, K. Bailey Physics Division, Argonne National Laboratory
A. Garcia, M. Sternberg, F. Wauters, D. Zumwalt, R. Hong,
Y. Bagdasarova, D. Storm, H.E. Svanson, G. Harper CENPA, University of Washington
X. Flechard, E. Liennard
LPC Caen
O. Naviliat-Cuncic NSCL, Michigan State University
PhD, Postdoc
$ PM DOE Early Career Research Grant, DOE CENPA, LPC $
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Limits with 0.1% 6He Experiment
26
90% C.L.
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The “Classic” 6He Experiment
27
C.H. Johnson, F. Pleasonton, T.A. Carlson, Phys.Rev. 1963
a = - 0.3308(30)
Measure 6Li recoil energy spectrum
with radiative correction from F. Glueck, Nucl. Phys A, 628, 493 (1998)
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Systematic Uncertainty Estimates
da x 10-3
Trap position stability 10 mm 0.15
Electric field stability 4x10-4 0.15
MCP timing resolution 100 ps (200 ns) 0.15
MCP efficiency calibration rel. 0.04%
30 mm 0.15
Beta detector calibration 0.30
0.42 (0.13%)
Need more detailed simulations on E-field distortions, beta detector response and beta backscattering
– Calibration with 6He background gas
– Photoionization of 4He
Study different range for beta scattering parameters in GEANT4
– Few % backscattering events, need to understand to rel. ~ 5%
– Tracking in MWPC for fiducial cuts
28
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Beta Detector System
29
Scintillator energy calibration, 207Bi
9% dE/E
• MWPC 94% efficiency • New double-layer frames for position
resolution + angle under construction • Be window leads to 150 keV loss +
large angle straggling • Explore other window materials
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First coincidence signals
30
October 2013