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Rare Isotope Science Project in Korea: RAON and nuclear theory

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Presentation on theme: "Rare Isotope Science Project in Korea: RAON and nuclear theory"— Presentation transcript:

1 Rare Isotope Science Project in Korea: RAON and nuclear theory
Youngman Kim Rare Isotope Science Project (RISP) Institute for Basic Science (IBS) ECT*-APCTP workshop (Sept.14-18)

2 Outline RISP in Korea Theory activities at RISP

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4 RAON Site Bird’s-eye view Area (Lot/Bldg): 952,066 m2 / 130,257 m2
Current RISP Office ~11 km

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6 RAON Concept Driver LINAC Post Accelerator ISOL system IF system
High intensity RI beams by ISOL & IF ISOL : direct fission of 238U by 70MeV proton IF by 200MeV/u, 8.3pμA 238U High quality neutron-rich RI beams 132Sn with up to ~250MeV/u, up to ~108 pps More exotic RI beams by ISOL+IF 20m ECR-IS (10keV/u, 12 pμA) LEBT 128.5m RFQ (300keV/u, 9.5 pμA) MEBT 100m SCL1 (18.5 MeV/u, 9.5 pμA) Driver LINAC Chg. Stripper SCL2 (200 MeV/u, 8.3 pμA for U+79) (600MeV, 660 μA for p) 375m 100m 80m ISOL Target 70m 20m MEBT RFQ CB HRMS IF Target μSR, Bio-medical RF Cooler SCL3 Cyclotron (p, 70 MeV, 1mA) 250m ECR-IS High-precision Mass Measurement IF Separator Gas Catcher Post Accelerator ISOL system IF system 110m 100m Low Energy Experiments Nuclear Astrophysics CB : Charge Breeder HRMS : High Resolution Mass Separator High Energy Experiments Nuclear Structure/ Symmetry Energy

7 KOBRA (KOrea Broad acceptance Recoil spectrometer and Apparatus)
Main facility for nuclear structure and nuclear astrophysics studies with low-energy stable and rare isotope beams Main Research Subject : 1) Nuclear structure of exotic nuclei near the drip lines 2) Astrophysically important nuclear reactions 3) Rare event study - Super Heavy Element (SHE), New isotopes 4) Nuclear physics with polarized beam/target etc - RIBs production via low-E in-flight method by multi nucleon trasfer reaction (ex. 44Ti) - Main Specification Maximum magnetic rigidity (Tm) ~3 Mass resolution stage 1 ~700 Dispersion stage 1 4.2 Momentum acceptance stage 1 ±4 Angular acceptance stage 2 40 (H) and 200 (V) Stage 1 F1 F2 Wien filter Stage 2 F0 In-flight separation or Beam transport Wien filter Big-bite Spectrometer F3 * Design Concept - Ion optics calculation was done using K-trace code (ray tracing) - Rotation of ‘stage 2’, variable position of Q-magnets in ‘stage 2’ are under consideration - Technical design is in progress F5 1) Two stage F4 - Stage 1 (F0~F3) : - Design of associate equipment Production and separation of RIBs via In-Flight method with high intensity SIBs from SCL * Associate equipments FP Equipments F0 RI production target, F3 gas-jet target, gamma-array, detection system, b-NMR F5 Focal plane detection system - Stage 2 (F3~F5) : Big-bite spectrometer with Wien filter  large acceptance [Gas-jet target] [PPAC] [Gamma array]

8 (Large Acceptance Multi-Purpose Spectrometer)
LAMPS (Large Acceptance Multi-Purpose Spectrometer) Asy-stiff Asy-soft Main facility for nuclear matter and nuclear reaction studies with intermediate energy stable and rare isotope beams Main Research Subject: Study of nuclear symmetry energy at supra-saturation density via heavy-ion collision experiment L.W. Chen et al., PRL 94, (2005) Beam Energy: up to 250 MeV/u Solenoid Spectrometer - Max. 1T solenoid magnet - TPC (~ 3 sr acceptance, charged particle tracking) - Scintillation counter (trigger & ToF) - Si-CsI (measure heavy fragment using E-E method) Dipole Spectrometer - Rotatable dipole magnet and focal plane detector (capable to study nuclear reaction) Neutron Wall (neutron tracking)

9 RISP Milestone Schedule
ECR SI Beam RFQ Beam SCL Demo Beam SCL SI Beam IF RI Beam ISOL SI Beam Cyclotron ISOL RI Beam DAY-1 Experiment Begin Construction Start Utility Supply Completion

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11 Theory activities at RISP; through international/domestic collaborations!
Boundaries of the nuclear landscape Covariant density functional theory (Shuangquan Zhang) ... Production of exotic nuclei and heavy elements Reaction models (DNS, …), reactions for astrophysics Equation of state of dense matter New vibrational modes and asymmetric matter (Panagiota Papakonstantinou) ... Symmetry energy of dense matter … (Mannque Rho, Friday) Neutron stars (Chang-Hwan Lee, Thursday) Nuclear structure and reactions from first principles Ab initio NCSM ... Unitarily transformed realistic interactions (Panagiota Papakonstantinou) Nuclear transport: quantum molecular dynamics, RBUU (Yujeong Lee, Thursday) chiral effective field theory, …

12 Asymmetric matter in a parity doublet model
Introduce two nucleon fields that transform in a mirror way under chiral transformations: “Linear sigma model with parity doubling,” C. E. DeTar and T. Kunihiro, Phys. Rev. D 39, 2805 (1989)

13 The state N+ is the nucleon N(938)
The state N+ is the nucleon N(938). while N- is its parity partner conventionally identified with N(1500). Cf.

14 Parity doublet model with HLS
Motivation: Lower m0 ? Non-zero isospin density (chemical potential) Lower Tc for (chiral) transitions?

15 Y. Motohiro, YK, M. Harada, PRC 92, 025201 (2015)

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17 slope parameter S0=31 MeV

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19 Phase diagrams for m0 = 900 MeV
solid: first-order, dashed: crossover point: critical point (second order) LGT: 1st 2nd Critical chemical potential drops a bit

20 Phase diagrams for m0 = 500 MeV
smaller m0 favors smaller critical density for chiral phase transition both in symmetric and asymmetric dense matter

21 Quantum Molecular Dynamics
Transport model : Model to treat non-equilibrium aspects of the temporal evolution of a collision. Many-body problem with nucleons Numerical simulation (event generator) Different methods for different energies Kyungil Kim (RISP), K. S. Lee (CNU), etc

22 Non-equilibrium aspects Equilibrated (decay statistically)
Time ~10-20 sec ~10-16 sec Non-equilibrium aspects Equilibrated (decay statistically) p n α Transport model QMD BUU Other model HIPSE DIT Statistical Model GEMINI SIMON EMPIRE

23 Initialization <Gaussian distribution>
σr, σp : widths in configuration and momentum spaces, respectively <Density distribution> - Wood-Saxon function d > 1.5 fm <Fermi momentum> <Pauli principle> <Momentum of a nucleon>

24 Propagation Skyrme parametrization for NN potential
Ref.) M. Papa PRC 64(2010)024612 <Equation of Motion>

25 Stability 9Be 40Ca <Propagation with stabilized nuclei>

26 N-N Collision In classical scattering, r1 𝑏< 𝑟 1 + 𝑟 2 b r2
Two particles are always scattered. 𝜎= π 𝑟 1 + 𝑟 2 2 In our model, If a distance, d, between two nucleons is smaller than b, d<b, there is always a collision try. Here, 𝝈 𝒕𝒐𝒕 is in-medium cross-section. Ref.) G.Li and R.Machleidt PRC 48, 1702, PRC 49, 566

27 Pauli blocking <x-space> <p-space>
<Phase space density for i th particle> Occupation number After a nucleon-nucleon collision , we calculate the 6-dim. phase space density for each nucleon. If this condition for any nucleon is not satisfied, that collision will be blocked by the Pauli principle.

28 Central and Peripheral Collisions
b=0 fm b=7 fm

29 Ab initio No Core Shell Model
Ab initio: nuclei from first principles using fundamental/realistic interactions without uncontrolled approximations. No core: all nucleons are active, no inert core. Shell model: harmonic oscillator basis Point nucleons

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32 Ab initio No Core Gamow Shell Model

33 Ab initio method and NN interaction
Unfortunately, the NN interaction at low energies needed for nuclear physics applications cannot be directly derived from QCD at the moment Ab initio theory requires, of course, a realistic NN interaction accurately describing NN scattering data and deuteron properties We use NNLOOPT and JISP16 in this study

34 6Li in ab initio No Core Shell Model: NCFC approach
NCFC model is a version of the ab initio no core shell model (NCSM) with a few important characteristics: (1) the use of interactions defined for an infinite Hilbert space, (2) extrapolating to the continuum limit (infinite matrix limit) (3) uncertainty estimation for the extrapolation. In collaboration with: Ik Jae Shin (RISP, IBS) James Vary, Pieter Maris (Iowa State U.) Christian Forssen (Chalmers U.), Jimmy Rotureau (FRIB, MSU)

35 converge more slowly, underbound by 1.44 MeV , underbound only by 0.46 MeV

36 Both are within 2% of the experimental value

37 reasonable converged, about 3-5% higher than experiments

38 Results from Ab initio No Core GSM
Preliminary!!! Energy of the ground state

39 Preliminary!!! Energy of a resonance state (2+, 1)

40 Preliminary!!! Imaginary part of the energy of (2+, 1) state

41 JISP16 vs Daejeon16 N3LO interaction ISTP
(inverse scattering tridiagonal potential) SRG (similarity renormalization group) SRG-evolved N3LO PET (phase equivalent transformation) JISP16 (J-matrix inverse scattering potential) Daejeon16 Ik Jae Shin (RISP, IBS), Andrey Shirokov (Moscow State U.) James Vary (Iowa State U.), et al, in preparation

42 6Li g.s. energy The results of stable nuclei seem to be improved.
N3LO-SRG N3LO-SRG-PET (Daejeon16) experimental value : MeV

43 8He g.s. energy Daejeon16 also gives reliable results even though for exotic nuclei. N3LO-SRG N3LO-SRG-PET (Daejeon16) experimental value : MeV

44 Thank you for your attention !


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