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Institute for Structure and Nuclear Astrophysics Nuclear Science Laboratory E381: Search of potential resonances in the 12 C+ 12 C fusion reaction using.

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Presentation on theme: "Institute for Structure and Nuclear Astrophysics Nuclear Science Laboratory E381: Search of potential resonances in the 12 C+ 12 C fusion reaction using."— Presentation transcript:

1 Institute for Structure and Nuclear Astrophysics Nuclear Science Laboratory E381: Search of potential resonances in the 12 C+ 12 C fusion reaction using charged- particle decays from the 24 Mg( ,  ’) 24 Mg* reaction X. Tang( 唐暁東 ), G. P. Berg, T. Kawabata, B. Bucher, F. Xiao, D. Patel, R. Talwar, A. Long, N. Yokota, U. Garg, M. Wiescher, Y.-W. Lui, K. Hatanaka, A. Tamii, Y. Fujita, E. Ganioglu, G. Susoy, B. Bilgier, H.C. Kozer, M. Freer University of Notre Dame, USA University of Kyoto, Japan Texas A&M University, USA Osaka University, Japan Istanbul University, Turkey University of Birmingham, UK

2 Institute for Structure and Nuclear Astrophysics Nuclear Science Laboratory Outline Why do we need resonance information from indirect measurement? Is it possible to get resonance information from 24 Mg( ,  ’)? How to select the 24 Mg states relevant to the 12 C+ 12 C fusion reaction? Rate estimation.

3 Institute for Structure and Nuclear Astrophysics Nuclear Science Laboratory Detect Fusion Residues Detect light charged particles Detect gamma rays E x ( 24 Mg)~E cm ( 12 C+ 12 C)+14 MeV

4 Institute for Structure and Nuclear Astrophysics Nuclear Science Laboratory Carbon burning in the universe The extrapolation to low energy is uncertain … and more experimental and theoretical studies are urgently needed. Fowler, Nobel Lecture (1983) NSAC Long Range Plan 2007

5 Institute for Structure and Nuclear Astrophysics Nuclear Science Laboratory Challenge for Laboratory nuclear-Astrophysics in Underground and Surface 2009: CLAUS2009 R. Cooper et al., APJ (2009) 702, 660 Gasques et al. PRC 72 (2005) 025806 Jiang et al. PRC 75 (2007) 015803 ? ? Hindrance? Large uncertainties in 12 C+ 12 C

6 Institute for Structure and Nuclear Astrophysics Nuclear Science Laboratory The proposed resonances at E cm =1.5 MeV (E x =15.5 MeV) T. Spillane et al., Strong resonance at 2.14 MeV with width <12keV; PRL98 (2007) 122501; dismissed by a recent experiment at Naples. R. Cooper et al., APJ (2009) 702, 660

7 Institute for Structure and Nuclear Astrophysics Nuclear Science Laboratory 24 Mg(a,a’) inelastic Search the possible resonances Direct measurement The exact cross section 12 C+ 13 C 13 C+ 13 C Provide potential to model the smooth behavior 12 C+ 13 C 13 C+ 13 C Provide potential to model the smooth behavior 12 C+ 13 C 13 C+ 13 C 12 C+ 12 C 12 C( 12 C,n) 23 Mg 12 C( 12 C,p) 23 Na 12 C( 12 C,a) 20 Ne 12 C( 12 C, 8 Be) 16 O 12 C( 12 C,a) 20 Ne

8 Institute for Structure and Nuclear Astrophysics Nuclear Science Laboratory Notre Dame-ANL-IU carbon fusion experiment A 5 MV Pelletron with ECR source in terminal. Will be installed at the end of 2011. Clover array at ANL Georgina at ND

9 Institute for Structure and Nuclear Astrophysics Nuclear Science Laboratory Naples : 10 puA beam; 1.5% eff.; proton channel only ; 0.5 evt/days; ND-ANL-IU: >40 puA beam; 45% eff.; both proton and alpha; 4*30*2 evt/days; If add particle + gamma coincidence: 240*8% evt/days

10 Institute for Structure and Nuclear Astrophysics Nuclear Science Laboratory Impact of the potential resonances to astrophysical reaction rate Carbon core burning Carbon shell burning Explosive Carbon burning Super-burst

11 Institute for Structure and Nuclear Astrophysics Nuclear Science Laboratory 16O   12C 12 C+ 12 C cluster components in 24 Mg (g.s.) Therefore, the 12 C+ 12 C resonant states could be strongly populated by the 24 Mg( ,  ’)! AMD+GCM calculation by Y. Kanada-Enyo

12 Institute for Structure and Nuclear Astrophysics Nuclear Science Laboratory (a) 4+4+ 2+2+ 2+2+ 2+2+ 0+0+ 4 + /2+ E x (MeV) Arbitrary unit 4+4+ 2+2+ 2+2+ 2+2+ 0+0+ 4 + /2+ E x (MeV) counts (b) Identified 0 + 2 + states coincide with 12C+12C ?? 2+3-4+2+3-4+ RCNP:+0.18 MeV; KVI:+0.10 MeV Preliminary Spectrum at 0 deg from E308 KVI

13 Institute for Structure and Nuclear Astrophysics Nuclear Science Laboratory Grand Raiden at RCNP, Osaka University Precise energy calibration (<20 keV)  confirm the correlation Excellent energy resolution (<50 keV)  Resolving states Measurement of angular distribution  Check spin assignment

14 Institute for Structure and Nuclear Astrophysics Nuclear Science Laboratory The predicted nuclear structure for the candidate states (14MeV<E x <17 MeV) J  should be 0 + /2 +. Decay mainly by p,  or 8 Be 12 C decay branching ratio (BR): BR<1E-5 (Ecm<3 MeV) BR~10% (Ecm=6 MeV)

15 Institute for Structure and Nuclear Astrophysics Nuclear Science Laboratory Decay spectroscopy: p,  and 8 Be Probe nuclear structure Enhance spin selection Goal: Try to find the signature for the 12C+12C states at Ecm> 3MeV(Ex>17 MeV) and then apply it to the states with Ecm<3 MeV (Ex<17MeV). Preliminary Data from E308 The p/  decay spectroscopy has been studied at 0 deg by E308. We will perform the decay measurement at the angle where the 2+ reach its maximum.

16 Institute for Structure and Nuclear Astrophysics Nuclear Science Laboratory The 12 C( 12 C, 8 Be) 16 O channel

17 Institute for Structure and Nuclear Astrophysics Nuclear Science Laboratory 8 Be decay dominates? 24Mg(a,a’+8Be): new way to investigate the clustering state

18 Institute for Structure and Nuclear Astrophysics Nuclear Science Laboratory Decay detector setup Decay eff: 3.6% (p and a) 0.9% (8Be)

19 Institute for Structure and Nuclear Astrophysics Nuclear Science Laboratory 5mb/sr; 20% background; 10 enA 388 MeV  beam; 2 mg/cm^2 Rate: 3.8x10 4 cnt/hr GR dispersion matching set up to get resolution < 50 keV (x 3 days) Energy calibration ( 400 MeV x 1% = 40 MeV, 3 magnetic field setting)  determine resonance energy with uncertianty < 20 keV (3 hr) Angular calibration (8 hr) Angular distribution (0, 2.5, 3.7, 5, 6, 7.4, 8.8, 10.2, and 11.6 (9 angles) (24 hours) Decay measurement (4 days) Thin target: 0.2 mg/cm 2 Decay eff: 3.6% (p and  ) 0.9% ( 8 Be) p/a: ~3000 cnt/day (12000 cnt/4 days) 8Be:~3000 cnt/4 days 12C/16O contamination: 1 day Total: 3 days+12 hours+1day+4 days+1 day~9 days + 12 hours

20 Institute for Structure and Nuclear Astrophysics Nuclear Science Laboratory Budget

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