Download 3-Bergeron_Lithium Loading

Phase stability and lithium
loading capacity in a liquid
scintillation cocktail
Denis E. Bergeron, H. Pieter Mumm, Mark Tyra
Physical Measurement Laboratory, National Institute of Standards and
Technology, Gaithersburg, MD, USA
LSC 2017, Copenhagen, 1 May 2017
Neutrino detection by LSC
• Inverse beta decay (threshold 1.8 MeV)
+
𝜈𝜈𝑒𝑒 + 𝑝𝑝 → 𝑒𝑒 + 𝑛𝑛
• Proton-rich target for good detection efficiency and energy resolution
• Loading cocktail with a neutron capture agent (Gd or 6Li) further improves
performance
𝑛𝑛 + 6Li → α + 𝑡𝑡 + 4.78 MeV
• Timing and pulse shape discrimination to reduce backgrounds from gammarays and neutrons
High-background applications
• Many large-scale liquid
scintillation detectors are
intended for detection of
solar or cosmic neutrinos,
requiring ultra-low
backgrounds*
• Recent interest in the reactor
flux and spectrum
anomalies** has prompted
the design of experiments
intended to operate with
much higher neutrino flux
• With volumes measured in
thousands of liters, price is a
concern
*Benziger and Calaprice (2016), Large-scale liquid scintillation detectors for solar neutrinos, Eur. Phys. J. A 52, 81.
**Ashenfelter, et al. (2016), The PROSPECT physics program, J. Phys. G, 43, 113001; An et al. (2016), Measurement of the
Reactor Antineutrino Flux and Spectrum at Daya Bay, Phys. Rev. Lett. 116, 061801.
Picking a LS cocktail to load
• Earlier work at NIST*
developed a formula
based on Quickszint,
loaded with up to 0.40 %
6Li by mass
• H/C: 1.5
• Quickszint no longer
available.
• Options?
*Fisher, et al. (2011), NIMA 646, 126-134
Bass, et al. (2013), ARI
Picking a LS cocktail to load
• Earlier work at NIST*
developed a formula
based on Quickszint,
loaded with up to 0.40 %
6Li by mass
• H/C: 1.5
• Quickszint no longer
available.
• Options?
*Fisher, et al. (2011), NIMA 646, 126-134
Bass, et al. (2013), ARI
Scintillant
Ultima Gold
HiSafe 2
Ultima Gold AB
HiSafe 3
HionicFluor
H/C
1.46
1.03
1.51
1.47
1.73
**Certain commercial materials are identified
to foster understanding. Such identification
does not imply recommendation by the
National Institute of Standards and
Technology, nor does it imply that they are
necessarily the best available for the purpose.
Picking a LS cocktail to load
• Earlier work at NIST*
developed a formula
based on Quickszint,
loaded with up to 0.40 %
6Li by mass
• H/C: 1.5
• Quickszint no longer
available.
• Options?
*Fisher, et al. (2011), NIMA 646, 126-134
Bass, et al. (2013), ARI
Scintillant
Ultima Gold
HiSafe 2
Ultima Gold AB
HiSafe 3
HionicFluor
H/C
1.46
1.03
1.51
1.47
1.73
**Certain commercial materials are identified
to foster understanding. Such identification
does not imply recommendation by the
National Institute of Standards and
Technology, nor does it imply that they are
necessarily the best available for the purpose.
Ultima Gold AB and HiSafe 3 show the best Li
loading capacity
Ultima Gold AB
600
550
1M
2M
4M
8M
450
turbid
400
turbid
350
300
Observed phase separation
0
1
2
f (% Li by mass)
1M
2M
4M
8M
450
350
250
Observed phase separation
500
tSIE
tSIE
500
400
HiSafe 3
550
3
turbid
300
250
0
0.5
1
1.5
f (% Li by mass)
2
In a long term experiment…
• Phase separation: separation into
aqueous and organic domains
• Turbidity: cloudiness due
to presence of many large
particles
A true microemulsion is thermodynamically
stable, optically isotropic, and has relatively
low viscosity. Aqueous domains (reverse
micelles) are of nanometer dimension.
The eye can be deceived
• Sometimes, an agitated emulsion
looks like a microemulsion
• Over time, thermodynamic instability
drives agglomeration of aqueous
domains  phase separation
• In a multi-year experiment, phase
stability is absolutely essential
Aging samples
140
UGAB
with 2.5 %
Li by mass
120
80
60
UGAB
40
20
0
UGAB with 1.5 % Li by mass
104
102
0
0.05
0.1
0.15
days
• Centrifugation can drive
phase separation
control
100
H#
H#
100
• Quench indicating parameters
based on the Compton
spectrum of a scintillant are
sensitive to phase dynamics
98
96
8 h centrifugation
94
92
0
10
days
20
Aging samples
0.5 % Li
0.75 % Li
H#
control
8 h centrifugation
80
H#
75
60
1.0 % Li
40
80
1.5 % Li
95
35
120
100
65
75
8 h centrifuge
20
2.5 % Li
No added Li
25
0
5
10 15
days
20
25
0
1
2
Mass fraction of Li / %
3
• Loading up to 1.0 % Li by mass
(with 8 mol/L LiCl) produced
stable microemulsions
Dynamic light scattering
2.5 % Li
water
10
H.D. / nm
15
1.5 % Li
5
0
Polydispersity Index
8 mol/L LiCl
0
0.2
0.4
0.4
0.3
0.2
0.1
0
0.2
faq
0.4
0.6
2.5 % Li
18
16
14
0.6
0.5
0
20
Polydispersity Index
H.D. / nm
20
0
0.5
10
20
30
40
20
30
40
2.5 % Li
0.4
0.3
0.2
0.1
0
0
10
telapsed / min
Conclusions: it works
• Very high loading
• Using 8 mol/L aqueous LiCl, we achieved stable
loading of up to 1 % Li by mass in Ultima Gold AB
• Cheap
• Commercially available scintillant and a simple
loading procedure
•Our formulation is being deployed in
experiments at NIST
•We have investigated light yield, optical
transmission, and material compatibilities for
the loaded UGAB (to be reported)
Tak