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Using LaBr 3 Gamma-ray Detectors for Precision Lifetime Measurements of Excited States in ‘Interesting’ Nuclei Paddy Regan Department of Physics University of Surrey, UK p.regan@surrey.ac.uk
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How is measuring the lifetime useful? Transition probability (i.e., 1/mean lifetime as measured for state which decays by EM radiation) (trivial) gamma-ray energy dependence of transition rate, goes as. E 2L+1 e.g., E 5 for E2s for example. Nuclear structure information. The ‘reduced matrix element’, B( L) tells us the overlap between the initial and final nuclear single-particle wavefunctions.
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Brighton & Surrey groups purchased 31 1.5” x 2” LaBr 3 detectors from St Gobain (Dec. 2012). Mounted into designed holders with Hamamatsu PMTs Jan 2013.
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FATIMA for DESPEC FATIMA = FAst TIMing Array = A high efficiency, gamma-ray detection array for precision measurements of nuclear structure in the most exotic and rare nuclei. Specs. –Good energy resolution. –Good detection efficiency –Excellent timing qualities (~100 picoseconds). (2012) Bought 31 x LaBr 3 1.5” x 2” crystals for array (expect 36 in total). Can use to measure lifetimes of excited nuclear states; provide precision tests of shell model theories of nuclear structure. UK contribution to DESPEC (Decay Spectroscopy) project within NUSTAR. Part of ~ £8M UK STFC NUSTAR project grant (runs to 2015).
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T 1/2 = 1.4ns Tests with 152 Eu source to measure lifetime of I =2 + 122 keV level in 152 Sm.
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137 Cs source gives (initial) test energy resolution of ~3.5% at 662 keV. Note presence of internal radioactivity in detector. PMT HV range ~1300 V 1436 keV EC (2 + → 0 + in 138 Ba) 789 keV + - In 138 Ce Ba x-rays from 137 Cs & EC from 138 La decay
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138 La, T 1/2 =1.02x10 11 years A.A.Sonzogni, NDS 98 (2003) 515 5+5+138 La 1435.8 138 Ba 82 2+2+ 0+0+ ec (66%) 0+0+ 2+2+ 138 Ce 80 788.7 - (34%)
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A ‘high(ish) background’ instrument… J. McIntyre et al., NIM A 652, 1, 2011, 201-204 Activity: ~0.7counts/sec./cm 3 ~0.1 counts/sec/cm 3 EC β-decay α 0-255 keV 788-1000 keV 1.5-3 MeV
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34 P 19
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Scientific Motivation for ‘Fast-Timing’ Studies in 34 P 34 P 19 has I =4 - state at E=2305 keV. Aim to measure a precision lifetime for 2305 keV state. WHY? A I =4 - → 2 + EM transition is allowed to proceed by M2 or E3 multipole gamma-rays. M2 and E3 decays can proceed by f 7/2 → d 3/2 => M2 multipole f 7/2 → s 1/2 => E3 multipole Lifetime and mixing ratio information gives direct values of M2 and E3 transition strength Direct test of shell model wfs… . ’ ’ ’ Z=15 = N=19
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34 P 19 (Simple) Nuclear Shell Model Configurations 20 1d 5/2 2s 1/2 1d 3/2 1f 7/2 20 1d 5/2 2s 1/2 1d 3/2 1f 7/2 I = 2 + [ 2s 1/2 x ( 1d 3/2 ) -1 ]I = 4 - [ 2s 1/2 x 1f 7/2 ] Theoretical predictions suggest 2 + state based primarily on [ 2s 1/2 x ( 1d 3/2 ) -1 ] configuration and 4 - state based primarily on [ 2s 1/2 x 1f 7/2 ] configuration. M2 decay can proceed via f 7/2 → d 3/2 ( j= l=2) transition. 15 protons 19 neutrons
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34 P 19 (Simple) Nuclear Shell Model Configurations 20 1d 5/2 2s 1/2 1d 3/2 1f 7/2 20 1d 5/2 2s 1/2 1d 3/2 1f 7/2 I = 2 + [ 2s 1/2 x ( 1d 3/2 ) -1 ]I = 4 - [ 2s 1/2 x 1f 7/2 ] Theoretical predictions suggest 2 + state based primarily on [ 2s 1/2 x ( 1d 3/2 ) -1 ] configuration and 4 - state based primarily on [ 2s 1/2 x 1f 7/2 ] configuration. M2 decay can go via f 7/2 → d 3/2 ( j= l=2) transition. 15 protons 19 neutrons
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34 P 19 (Simple) Nuclear Shell Model Configurations 20 1d 5/2 2s 1/2 1d 3/2 1f 7/2 I = 2 + [ 2s 1/2 x ( 1d 3/2 ) -1 ] Theoretical predictions suggest 2 + state based primarily on [ 2s 1/2 x ( 1d 3/2 ) -1 ] configuration and 4 - state based primarily on [ 2s 1/2 x 1f 7/2 ] configuration. M2 decay can go via f 7/2 → d 3/2 ( j= l=2) transition. M2 s.p. transition
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20 1d 5/2 2s 1/2 1d 3/2 1f 7/2 20 1d 5/2 2s 1/2 1d 3/2 1f 7/2 I = 2 + [ 1d 3/2 x ( 2s 1/2 ) -1 ]I = 4 - [ 2s 1/2 x 1f 7/2 ] Theoretical predictions suggest 2 + state based primarily on [ 2s 1/2 x ( 1d 3/2 ) -1 ] configuration with some small admixture of [ 1d 3/2 x ( 1s 1/2 ) -1 ] 4 - state based primarily on [ 2s 1/2 x 1f 7/2 ] configuration. E3 can proceed by f 7/2 → s 1/2 ( j= l=3 transition). Admixtures in 2 + and 4 - states allow mixed M2/E3 transition. 15 protons 19 neutrons
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DESPEC LaBr 3 Detectors ‘Test’ Experiment 18 O( 18 O,pn) 34 P fusion-evaporation @36 MeV. 34 P cross-section, ~ 5 – 10 mb Target, 50mg/cm 2 Ta 2 18 O enriched foil 18 O. Beam from Bucharest Tandem (~20pnA). Array 8 HPGe and 7 LaBr 3 (Ce) detectors -3 (2”x2”) cylindrical -2 (1”x1.5”) conical -2 (1.5”x1.5”) cylindrical
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4-4-
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4-4-
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T 1/2 (4 - ) = 2.0(2) ns ; 4 - → 2 + = M2 decay. Consistent with ‘pure’ f 7/2 → d 3/2 transition. Precision test of nuclear shell model at N=20 {429,1876} 4-4- {429,1048}
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P.J.Mason et al., Phys. Rev C85, 064303 (2012)
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138 Ce
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( h 11/2 ) -2 only N=80 Isotones 0+0+ 2+2+ 4+4+ 6+6+ 8+8+ 10 + isomer Primarily ( d 5/2 ) 2 Primarily ( g 7/2 ) 2 N = 80 isotones above Z = 50 display 10 + seniority isomers from coupling of ( h 11/2 ) -2 6 + level decays also usually ‘hindered’ e.g., in 136 Ba,T 1/2 = 3.1(1)ns. Thought to be due to change in configuration and seniority.
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N=80 Isotones Neighbouring N=80 nuclei, 138 Ce and 140 Nd expected to show similar 6 + → 4 + hindrance. Competing transitions to negative parity states E1 decays, forbidden in truncated shell model space.
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Restricted basis SM calculations give reasonable comparison with experimental (near- yrast) states in 138 Ce. What about transition rates?
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130 Te( 12 C,4n) 138 Ce @56 MeV
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138 Ce 80
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S.-J. Zhu et al. Chin.Phys.Lett. 16, 635 (1999) T 1/2 = 140(11)ps Using “delayed” HPGe gate 138 Ce – Lifetime of the 11 + State
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188 W
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2 neutrons more than heaviest stable Tungsten (Z=74) isotope ( 186 W). Populate 188 W using 186 W( 7 Li,ap) 188 W ‘incomplete fusion’ reaction. (Not really a fusion-evap reaction, but populates medium spin states). See e.g., Dracoulis et al., J. Phys. G23 (1997) 1191-1202 110 111 112 113 114 115 N
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Half-life of the yrast 2 + state in 188 W Neutron-rich A ~ 190 nuclei, a long predicted prolate – oblate shape transition region. e.g. Bengtsson et al. PLB190 (1987) 1 Unusual (energy) deviation at 190 W compared to trend of other nuclides. Measurement of B(E2;2 + → 0 + ) gives best measure of (evolution of) low-lying collectivity
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Half-life of the yrast 2 + state in 188 W 16 mg/cm 2 186 W target with thick Pb backing 186 W( 7 Li, p) 188 W. 31-, 33-MeV beam (Coul. Barr. ~ 29 MeV) Estimated 0.1-1 mb Strongest channels: 187 Re (1-p transfer) 189 Ir (fusion-evap)
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Sum of time differences between 143-keV (2->0) transition and any higher lying feeding transition.
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T 1/2 =0.87(12) ns Time difference between 143 keV 2 + → 0 + and feeding transitions.
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188 W
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Other Recent Uses of Fatima Detectors 21 detectors went RIKEN for use in EURICA array from Nov. 2012 (see talk by GL). 8 detectors used with EXOGAM@ILL from Feb. – March 2013 for use in 235 U(n,f) experimental campaign.
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F.Browne, H. Watanabe, A. Bruce, T. Sumikama et al.,
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140 keV 2 + → 0 + in 104 Zr Demonstrates that beta-gamma time differences can be used in projectile fragmentation/fission spectroscopy to measure, e.g., 2+ lifetimes in many, even-even, exotic nuclei, down to ~100 ps?
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Compares with T 1/2 =2.0(1) ns measurement by Hwang et al., Phys. Rev. C73, 044316 (2006)
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EXILL + FATIMA EXOGAM + FATIMA LaBr 3 array at ILL Grenoble Ge-Ge-LaBr 3 -LaBr 3 quadruple coincs between prompt gammas from fission fragments in 235 U(n,f) reaction using thermal neutrons.. Massive data set, under analysis (led by Koln group)
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Possible array configuration at focal plane of RITU spectrometer at JYFL
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Characterized LaBr 3 detectors for fast-timing measurements in the 100 ps to few ns range. 34 P M2 strength measured approaching the island of inversion for N~20. 188 W show reduction in ground state collectivity compared to lighter W isotopes. Other measurements using these detectors at EXILL+FATIMA (2013) ; EURICA (2013); DESPEC-FATIMA@FAIR (~2017) ; decay spect at RITU (from Mid 2014).
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Acknowledgements Zsolt Podolyák, Peter Mason, Thamer Alharbi, Christopher Townsley (Surrey) Alison Bruce, Oliver Roberts, Frank Browne (Brighton) Nicu Marginean et al., (Bucharest) Funding for detectors and DAQ from STFC UK.
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