Presentation is loading. Please wait.

Presentation is loading. Please wait.

Acknowledgements NSCL/MSU (USA): P. Danielewicz, C.K. Gelbke, W.G. Lynch, M.B. Tsang, W.P. Tan, REU students INFN-Catania (Europe) LLNL (USA): D.A. Brown.

Published by Modified over 8 years ago

Similar presentations

Presentation on theme: "Acknowledgements NSCL/MSU (USA): P. Danielewicz, C.K. Gelbke, W.G. Lynch, M.B. Tsang, W.P. Tan, REU students INFN-Catania (Europe) LLNL (USA): D.A. Brown."— Presentation transcript:

1 Acknowledgements NSCL/MSU (USA): P. Danielewicz, C.K. Gelbke, W.G. Lynch, M.B. Tsang, W.P. Tan, REU students INFN-Catania (Europe) LLNL (USA): D.A. Brown IU and WU (USA) :HiRA groups GANIL (Europe): A. Chbihi, J. Frankland Laval Univ. (Canada): F. Grenier, R. Roy

2 Our “femtoscopes” 1+R(E * ) E * (MeV) p-p d-   - 6 Li How to get sizes? Different sizes from different particle species? Role of (N/Z) degree of freedom? Can we isolate and study exotic unbound states (astrophysics and physics at-and-beyond the drip lines)?

3 G. Verde at al., PRC65 (2002) C(q)= Size (fm) Width (MeV/c) Our “femstoscopes” - How to use them? q (MeV/c) 1+R(q) G. Verde et al., PRC65, 054609 (2002) q (MeV/c) 1+R(q) p-p d-  Size (fm) Width (MeV/c) 1 st Peak (resolution) 2 nd Peak

4 Doing femtoscopy with Imaging (a.a.) Source size Source size from peak shape/width Y total =Dynamical + Sec. Decays Y fast + Y slow Images of of the dynamically emitting source (pre-equil.) Slow sources (Sec. decays) 14 N+ 197 Au E/A=75 MeV P. Danielewicz, D.A. Brown qe G. Verde et al., PRC (2002)

5 Output of imaging femtoscopy 7 5 4 2.5 3.1 2.9 Size (fm) (Fast) Source Sizes Total momentum Long-lived source (%) Total momentum Fast/Slow contributions Probing the dynamical proton emitting source No shape analyses

6 Probing dynamical sources in BUU S imaging (r) vs S BUU (r) Long-lived emissions not handled properly by BUU BUU sources require renormalization

7 Probing transport theories Ar+Sc central e q r (fm) S(r) (fm -3 ) Imaging Data BUU free  NN BUU red  NN Models E/A=120 MeV G. Verde et al., PRC (2003)

8 Isospin-dependent BUU (IBUU) Density dependence of the symmetry energy Asy-Stiff Asy-Soft n/p emmission times Correlation functions neutron-neutron proton-proton proton-neutron 0.0 0.5 1.0 1.5 1 2 3 4 1 3 5 7 q (MeV/c) 1+R(q) IBUU: 52 Ca+ 48 Ca E/A=80 MeV Asy-Stiff Asy-Soft

9 Neutron-proton correlation exps 1 2 3 4 neutron-proton q (MeV/c) 1+R(q) Asy-stiff Asy-soft 112,124 Sn+ 58,64 Ni E/A=35 MeV Neutrons Protons LNS-Catania, INFN-Catania, INFN-Bari, Lund University Protons Neutrons Future programs - higher resolution and efficiency? (GANIL, MSU, programs in progress) Asy-BUU predictions Difficult experiments - neutron detection! n/p chronology, R. Ghetti et al.

10 p-p source shape and Asy-EOS Asy-soft: larger source, longer proton emission times Measure at q<15 MeV/c required!! Asy-stiff r 1/2 ~3.6 fm Asy-soft r 1/2 ~4.4 fm r (MeV/c) S(r) (a.u.) p-p Sources 1+R(q) q (MeV/c) Asy-stiff Asy-soft Correlations

11 Isospin effects in Two-proton sources Central collisionsSources Protons from secondary decays: more in 112 Sn+ 112 Sn Preliminary LASSA 112 Sn+ 112 Sn vs 124 Sn+ 124 SnE/A=50 MeV, central

12 Isospin effects - energy gated correlations q (MeV/c) 1+R(q) E 1,E 2 >60 MeVE 1,E 2 <50 MeV 124 Sn+ 124 Sn 112 Sn+ 112 Sn 124 Sn+ 124 Sn 112 Sn+ 112 Sn Need higher resolution Explore the shape at low q-values Slow sources dominate Dynamical sources dominate

13 HiRA@MSU - experiment in 2006 40,48 Ca + 40,48 Ca E/A=80 MeV HiRA & MSU-4  Correlation functions Isotopic effects on high resolution correlation functions - low q-values measured Extend to several particle species… but collective motion and event characterization need to be controlled (MSU 4  ) Si strips X-Y CsI Angular resolution ! Event characterization

14 Complex particles: HBT and nuclear thermometers Sensitive to geometry only Correlation function Numerator (coinc) Sensitive to T: thermometer

15 d-  correlations in pure-thermal models Problems in reproducing the line shape of R(q)! J. Pochodzalla et al., PRC35, 1695 (1987)

16 Effects of position-momentum correlations Apparent source size reduction Shape of correlation functions depends on both source size and temperature More relevant for massive particles Position - relative momentum correlations Thermal Thermal+ Collective

17 Beam z x y Elongated source in quasi-central events Xe+Au collisions, E/A=50 MeV Comparison to data improves with v rad ~ 0.1-0.2 c and emission densities  ~ 0.1-0.4   The correlation functions depends on the interplay temperature/collective motion ! Thermal only V rad =0 0.1 0.2 0.3 G. Verde et al., Physics Letters B, (2007), in press T=4 MeV

18 Sizes/Densities from correlations Higher densities from more energetic particles p-p  0 ~ 0.5 d-  0 ~ 0-1-0.4 p-p sources more localized than d-  sources! Particle emission hierarchy (EES model, W. Friedman) p-p d- 

19 HIC as a spectroscopic tool Several unbound states are produced in just one single HIC experiment - reconstruct unbound species with correlations –Ex: 8 B*---> p+ 7 Be, 10 C--->2p+2 , etc. Relative heights of peak heights sensitive to spin of 8 Be states LASSA data W.P.Tan, PRC (2004) States of 8 B p+ 7 Be 0.774 (?) 1.4 (?) 2.32 8B8B 1+1+ 3+3+

20 Sequential decay modes of 12 C and 10 C Peripheral collisions 12 C+ 24 MgE/A=53, 95 MeV (Indra@GANIL) Decay of 12 C and 10 C quasi projectiles (QP*) 12 C*-->  part. correlations 10 C*-->  +p+p4-part. Correlations

21 Event mixing Modified event mixing 3  correlation function - 12 C* decays E* = E k + Q( 12 C-->3  ) Sequential decay through 8 Be contributes strongly 12 C  8 Be+   2  Sequential decays

22 10 C states excited states Final state: Always 2  +2p … but different paths are possible 10 C  6 Be+   (2p+  )  10 C  8 Be+  p   (  +  )  p 10 C  9 B+p   (  +  p)  p

23 E* = E k + Q( 10 C-->2  p) 2  +2p correlations - states in 10 C Evidence for sequential decays - 9 B channel the most favored F. Grenier, Laval Univ, PhD Thesis, 2006 F. Grenier, A. Chbihi, G. Verde et al., submitted E k (MeV) 9 B+p 8 Be+2p 6 Be+ 

24 High angular resolution experiment Dedicated experiment with radioactive beams: 10 C+ 9 Be  p+p+  E/A=10.7 MeV HiRA: 4-body correlations High high angular resolution Results in agreement with HIC experiment with stable beams! Charity et al., PRC (R) (2007)

25 Conclusions Femtoscopes at intermediate energies Imaging: sizes, probes of transport theories, symmetry energy in Asy-EOS Complex particles correlations: 1+R sensitive to both Temperature and Volume (collective motion) Multi-particle correlations in HIC as a spectroscopic tool: Several nuclear exotic species in one single experiment! Femtoscopy/correlations require high resolution… but it is worth the money! Tools to access dynamics/thermodynamics/structure

26 Detector: Three stage ΔE1-ΔE2-E - nTD Si-Si-CsI telescope  E2 used as a silicon det and as a photodiode for CsI(Tl) Pulse Shape Analysis in  E1 nTD Silicon detector to extract Z and A with low thresholds Full Digital Electronics On-line fast DSP / on-line calibration procedures Granularity and angular resolution Compactness, flexibility, transportability and… Neutrons capabilities(?) Detector: Three stage ΔE1-ΔE2-E - nTD Si-Si-CsI telescope  E2 used as a silicon det and as a photodiode for CsI(Tl) Pulse Shape Analysis in  E1 nTD Silicon detector to extract Z and A with low thresholds Full Digital Electronics On-line fast DSP / on-line calibration procedures Granularity and angular resolution Compactness, flexibility, transportability and… Neutrons capabilities(?) G.Poggi – XVColloque-Ganil-2006 CsI(Tl) H.I. ΔE1ΔE2 Si 300μm 700μm 30-100 mm ? FAZIA - Four-  A-Z Identif Array R&D phase (Working groups already active) Europe, India

27 Monolitic detector telescopes  E stage directly implemented on the E detector Very low identification thresholds (~300-400 AKeV for N isotopes!) Position sensitivity ~ 0.1 mm : high angular resolution F. Amorini et al., INFN-LNS, Catania

Download ppt "Acknowledgements NSCL/MSU (USA): P. Danielewicz, C.K. Gelbke, W.G. Lynch, M.B. Tsang, W.P. Tan, REU students INFN-Catania (Europe) LLNL (USA): D.A. Brown."

Similar presentations

Exploring the drip lines: where are the proton and neutron drip lines exotic decay modes: - two-proton radioactivity -  -delayed multi-particle emission.

Exploring the drip lines: where are the proton and neutron drip lines exotic decay modes: - two-proton radioactivity -  -delayed multi-particle emission.
Γ spectroscopy of neutron-rich 95,96 Rb nuclei by the incomplete fusion reaction of 94 Kr on 7 Li Simone Bottoni University of Milan Mini Workshop 1°-

Γ spectroscopy of neutron-rich 95,96 Rb nuclei by the incomplete fusion reaction of 94 Kr on 7 Li Simone Bottoni University of Milan Mini Workshop 1°-
Exochim & Farcos collaboration: L. Acosta, F. Amorini, A. Anzalone, L. Auditore, G. Cardella, A. Chbihi, E. De Filippo, L. Francalanza, E. Geraci, C. Guazzoni,

Exochim & Farcos collaboration: L. Acosta, F. Amorini, A. Anzalone, L. Auditore, G. Cardella, A. Chbihi, E. De Filippo, L. Francalanza, E. Geraci, C. Guazzoni,
Systematics of Temperature Measurements with ALADIN ALADIN S114 Spring 1993.

Systematics of Temperature Measurements with ALADIN ALADIN S114 Spring 1993.
Neutron Number N Proton Number Z a sym =30-42 MeV for infinite NM Inclusion of surface terms in symmetry.

Neutron Number N Proton Number Z a sym =30-42 MeV for infinite NM Inclusion of surface terms in symmetry.
Task10 : Physics & Instrumentation Subtask: Single Particle & Collective Properties ( Contributors: Angela Bonaccorso, Roy Lemmon, Valerie Lapoux, Yorick.

Task10 : Physics & Instrumentation Subtask: Single Particle & Collective Properties ( Contributors: Angela Bonaccorso, Roy Lemmon, Valerie Lapoux, Yorick.
Possibilities for Nuclear Physics at the Madrid Tandem Hans O. U. Fynbo Department of Physics and Astronomy University of Aarhus, Denmark Nuclear physics.

Possibilities for Nuclear Physics at the Madrid Tandem Hans O. U. Fynbo Department of Physics and Astronomy University of Aarhus, Denmark Nuclear physics.
Preliminary results from a study of isospin non-equilibrium E. Martin, A. Keksis, A. Ruangma, D. Shetty, G. Souliotis, M. Veselsky, E. M. Winchester, and.

Preliminary results from a study of isospin non-equilibrium E. Martin, A. Keksis, A. Ruangma, D. Shetty, G. Souliotis, M. Veselsky, E. M. Winchester, and.
The National Superconducting Cyclotron State University Betty Tsang Constraining neutron star matter with laboratory experiments 2005.

The National Superconducting Cyclotron State University Betty Tsang Constraining neutron star matter with laboratory experiments 2005.
12C(p,g)13N g III. Nuclear Reaction Rates 12C 13N Nuclear reactions

12C(p,g)13N g III. Nuclear Reaction Rates 12C 13N Nuclear reactions
Limits of Stability Neutron Drip Line? Proton Drip Line? Known Nuclei Heavy Elements? Fission Limit?

Limits of Stability Neutron Drip Line? Proton Drip Line? Known Nuclei Heavy Elements? Fission Limit?
For more information about the facility visit: For more information about our group visit:

For more information about the facility visit: For more information about our group visit:
Proton and Two-Proton Decay of a High-Spin Isomer in 94 Ag Ernst ROECKL GSI Darmstadt and Warsaw University.

Proton and Two-Proton Decay of a High-Spin Isomer in 94 Ag Ernst ROECKL GSI Darmstadt and Warsaw University.
Germany's United States 2 Germany 0 FIFA Women’s World Cup Semifinal.

Germany's United States 2 Germany 0 FIFA Women’s World Cup Semifinal.
E432a: Decay of Highly Excited Projectile-like Fragments Formed in dissipative peripheral collisions at intermediate energies 1.Understanding thermodynamic.

E432a: Decay of Highly Excited Projectile-like Fragments Formed in dissipative peripheral collisions at intermediate energies 1.Understanding thermodynamic.
First simulations of FAZIA Napoli 3-5 September 2007.

First simulations of FAZIA Napoli 3-5 September 2007.
Zbigniew Chajęcki National Superconducting Cyclotron Laboratory Michigan State University Probing reaction dynamics with two-particle correlations.

Zbigniew Chajęcki National Superconducting Cyclotron Laboratory Michigan State University Probing reaction dynamics with two-particle correlations.
Two- and multi-particle correlation studies Correlations as probes for spectroscopy and dynamics [dynamics]  [spectroscopy] Nuclear equation of state;

Two- and multi-particle correlation studies Correlations as probes for spectroscopy and dynamics [dynamics]  [spectroscopy] Nuclear equation of state;
Constraining the EoS and Symmetry Energy from HI collisions Statement of the problem Demonstration: symmetric matter EOS Laboratory constraints on the.

Constraining the EoS and Symmetry Energy from HI collisions Statement of the problem Demonstration: symmetric matter EOS Laboratory constraints on the.
- Mid-rapidity emission in heavy ion collisions at intermediate energies - Source reconstruction - Free nucleon multiplicities - Neutron/proton ratio of.

- Mid-rapidity emission in heavy ion collisions at intermediate energies - Source reconstruction - Free nucleon multiplicities - Neutron/proton ratio of.

Similar presentations

Ads by Google