Role of mass asymmetry in fusion of super-heavy nuclei

Slides:

Advertisements

Similar presentations

Accelerator Physics, JU, First Semester, (Saed Dababneh).

Advertisements

SYNTHESIS OF SUPER HEAVY ELEMENTS

Viola and the Heavy Elements W. Loveland Oregon State University.

Lorentzian-like models of E1 radiative strength functions V. A. Plujko, O. M. Gorbachenko, E. V. Kulich Taras Shevchenko National Kyiv University, Ukraine.

NUCLEAR REACTION MODELS FOR SYSTEMATIC ANALYSIS OF FAST NEUTRON INDUCED (n,p) REACTION CROSS SECTIONS M.Odsuren, J.Badamsambuu, G.Khuukhenkhuu Nuclear.

The peculiarities of the production and decay of superheavy nuclei M.G.Itkis Flerov Laboratory of Nuclear Reactions, JINR, Dubna, Russia.

What have we learned last time? Q value Binding energy Semiempirical binding energy formula Stability.

W. Udo Schröder, 2007 Spontaneous Fission 1. W. Udo Schröder, 2007 Spontaneous Fission 2 Liquid-Drop Oscillations Bohr&Mottelson II, Ch. 6 Surface & Coulomb.

The Dynamical Deformation in Heavy Ion Collisions Junqing Li Institute of Modern Physics, CAS School of Nuclear Science and Technology, Lanzhou University.

Systematical calculation on alpha decay of superheavy nuclei Zhongzhou Ren 1,2 ( 任中洲 ), Chang Xu 1 ( 许昌 ) 1 Department of Physics, Nanjing University,

Kazimierz What is the best way to synthesize the element Z=120 ? K. Siwek-Wilczyńska, J. Wilczyński, T. Cap.

沈彩万湖州师范学院 8 月 11 日 ▪ 兰州大学准裂变与融合过程的两步模型描述合作者： Y. Abe, D. Boilley, 沈军杰.

Fusion-Fission Dynamics for Super-Heavy Elements Bülent Yılmaz 1,2 and David Boilley 1,3 Fission of Atomic Nuclei Super-Heavy Elements (SHE) Measurement.

THE FISSION BARRIERS OF SUPERHEAVY AND EXOTIC NUCLEI Fedir A. Ivanyuk 1 and Krzysztof Pomorski 2 1 Institut for Nuclear Research, Kiev, Ukraine 2 Theoretical.

Relative kinetic energy correction to fission barriers 1. Motivation 2. Results for A= systems 3. A cluster model perspective 4. Prescription based.

NECK FRAGMENTATION IN FISSION AND QUASIFISSION OF HEAVY AND SUPERHEAVY NUCLEI V.A. Rubchenya Department of Physics, University of Jyväskylä, Finland.

1 Role of the nuclear shell structure and orientation angles of deformed reactants in complete fusion Joint Institute for Nuclear Research Flerov Laboratory.

25 9. Direct reactions - for example direct capture: Direct transition from initial state |a+A> to final state B +  geometrical.

Rate Constants and Kinetic Energy Releases in Unimolecular Processes, Detailed Balance Results Klavs Hansen Göteborg University and Chalmers University.

The Theory of Partial Fusion A theory of partial fusion is used to calculate the competition between escape (breakup) and absorption (compound-nucleus.

Production of elements near the N = 126 shell in hot fusion- evaporation reactions with 48 Ca, 50 Ti, and 54 Cr projectiles on lanthanide targets Dmitriy.

W. Udo Schröder, 2007 Semi-Classical Reaction Theory 1.

The study of fission dynamics in fusion-fission reactions within a stochastic approach Theoretical model for description of fission process Results of.

Microscopic-macroscopic approach to the nuclear fission process

Aim  to compare our model predictions with the measured (Dubna and GSI) evaporation cross sections for the 48 Ca Pb reactions. Calculations.

Α - capture reactions using the 4π γ-summing technique Α. Lagoyannis Institute of Nuclear Physics, N.C.S.R. “Demokritos”

Opportunities for synthesis of new superheavy nuclei (What really can be done within the next few years) State of the art Outline of the model (4 slides.

Incomplete fusion studies near Coulomb barrier Pragya Das Indian Institute of Technology Bombay Powai, Mumbai , India.

Kazimierz 2011 T. Cap, M. Kowal, K. Siwek-Wilczyńska, A. Sobiczewski, J. Wilczyński Predictions of the FBD model for the synthesis cross sections of Z.

Competition between compound-nucleus formation and quasi-fission in heavy element synthesis B.B.Back Argonne National Laboratory.

106 th Session of the JINR Scientific Council September 24-25, 2009, Dubna Perspectives of JINR – ORNL Collaboration in the Studies of Superheavy Elements.

Nuclear deformation in deep inelastic collisions of U + U.

II. Fusion and quasifission with the dinuclear system model Second lecture.

Isotope dependence of the superheavy nucleus formation cross section LIU Zu-hua( 刘祖华） (China Institute of Atomic Energy)

POPULATION OF GROUND-STATE ROTATIONAL BANDS OF SUPERHEAVY NUCLEI PRODUCED IN COMPLETE FUSION REACTIONS A.S. Zubov, V.V. Sargsyan, G.G. Adamian, N.V.Antonenko.

Can we constrain the fusion hindrance? David BOILLEY and Hongliang LÜ ( 吕宏亮 ) GANIL and Normandie Université Yasuhisa ABE ( 阿部恭久 ) RCNP, Osaka: ( 大阪大学核物理研究センター.

Neutron enrichment of the neck-originated intermediate mass fragments in predictions of the QMD model I. Skwira-Chalot, T. Cap, K. Siwek-Wilczyńska, J.

Recent improvements in the GSI fission model

激发能相关的能级密度参数和重核衰变性质叶巍（东南大学物理系南京）. 内容 ◆ 问题背景 ◆ 理论模型 ◆ 计算结果和结论.

Some aspects of reaction mechanism study in collisions induced by Radioactive Beams Alessia Di Pietro.

Quasifission reactions in heavy ion collisions at low energies A.K. Nasirov 1, 2 1 Joint Institute for Nuclear Research, Dubna, Russia 2 Institute.

NUCLEAR LEVEL DENSITIES NEAR Z=50 FROM NEUTRON EVAPORATION SPECTRA IN (p,n) REACTION B.V.Zhuravlev, A.A.Lychagin, N.N.Titarenko State Scientific Center.

W. Nazarewicz. Limit of stability for heavy nuclei Meitner & Frisch (1939): Nucleus is like liquid drop For Z>100: repulsive Coulomb force stronger than.

Role of the fission in the r-process nucleosynthesis - Needed input - Aleksandra Kelić and Karl-Heinz Schmidt GSI-Darmstadt, Germany What is the needed.

Study on Sub-barrier Fusion Reactions and Synthesis of Superheavy Elements Based on Transport Theory Zhao-Qing Feng Institute of Modern Physics, CAS.

1 Synthesis of superheavy elements with Z = in hot fusion reactions Wang Nan College of Physics, SZU Collaborators: S G Zhou, J Q Li, E G Zhao,

Microscopic-macroscopic approach to the nuclear fission process Aleksandra Kelić and Karl-Heinz Schmidt GSI-Darmstadt, Germany

C. M. Folden III Cyclotron Institute, Texas A&M University NN2012, San Antonio, Texas May 31, 2012.

The de-excitation code ABLA07 Aleksandra Keli ć, Maria Valentina Ricciardi and Karl-Heinz Schmidt GSI Darmstadt, Germany.

Observation of new neutron-deficient multinucleon transfer reactions

Nuclear Reaction Mechanisms in Heavy Ion Collisions 1 Joint Institute for Nuclear Research, Dubna, Russia Nasirov A.K. 1 Lecture III 1 Permanent position.

Time dependent GCM+GOA method applied to the fission process ESNT janvier / 316 H. Goutte, J.-F. Berger, D. Gogny CEA/DAM Ile de France.

Systematical Analysis of Fast Neutron Induced Alpha Particle Emission Reaction Cross Sections Jigmeddorj Badamsambuu, Nuclear Research Center, National.

March, 2006SERC Course1  Z>92 (Heaviest Element in Nature) and upto Z= achieved by n irradiation or p,  and d bombardment in Cyclotron ( )

Decay scheme studies using radiochemical methods R. Tripathi, P. K. Pujari Radiochemistry Division A. K. Mohanty Nuclear Physics Division Bhabha Atomic.

Dynamical Model of Surrogate Reaction Y. Aritomo, S. Chiba, and K. Nishio Japan Atomic Energy Agency, Tokai, Japan 1. Introduction Surrogate reactions.

Lecture 4 1.The role of orientation angles of the colliding nuclei relative to the beam energy in fusion-fission and quasifission reactions. 2.The effect.

Lecture 3 1.The potential energy surface of dinuclear system and formation of mass distribution of reaction products. 2.Partial cross sections. 3. Angular.

Lesson 14 The Transuranium Elements. The Basics 117 known elements, 1-118, no 117 All elements beyond 92 man-made.

Study of Heavy-ion Induced Fission for Heavy Element Synthesis

HEAVY ELEMENT RESEARCH AT THE FLNR (DUBNA)

采用热熔合方法合成超重核的理论研究王楠深圳大学合作者: 赵恩广 (中科院理论物理所) 周善贵 (中科院理论物理所)

Sensitivity of reaction dynamics by analysis of kinetic energy spectra of emitted light particles and formation of evaporation residue nuclei.

Aleksandra Kelić GSI – Darmstadt

Intermediate-mass-fragment Production in Spallation Reactions

The role of fission in the r-process nucleosynthesis

Microscopic-macroscopic approach to the nuclear fission process

sinv in ABLA Particle-decay width in Weisskopf-Ewing approach:

Catalin Borcea IFIN-HH INPC 2019, Glasgow, United Kingdom

Presentation transcript:

Role of mass asymmetry in fusion of super-heavy nuclei K. Siwek- Wilczyńska, I. Skwira-Chalot, J. Wilczyński aim  to compare our model predictions with the measured (Dubna, GSI, Riken) evaporation-residue cross sections for synthesis of super-heavy nuclei in xn reactions.  to predict cross sections for the synthesis of new super-heavy nuclei in cold and hot fusion reactions.  to verify the fusion hindrance factor (strongly dependent on the mass asymmetry).

(synthesis) = (capture) × P(fusion) × P(survive) Systematic studies based on experimental data:  (capture) - the „diffused-barrier formula” ( 3 parameters): W. Świątecki, K. Siwek-Wilczyńska, J. Wilczyński Phys. Rev. C 71 (2005) 014602, Acta Phys. Pol. B34(2003) 2049 Formula derived assuming: Gaussian shape of the fusion barrier distribution Classical expression for σfus(E,B)=πR2(1-B/E) A 2 fit to 48 experimental near-barrier fusion excitation functions in the range of 40 < ZCN < 98 resulted in systematics that allow us to predict values of the three parameters B0, w, R (K. Siwek-Wilczyńska, J. Wilczyński Phys. Rev. C 69 (2004) 024611)

cap(subcritical l ) = cap for E ≤ Bo For very heavy systems a range of partial waves contributing to CN formation is limited (critical angular momenta for disappearing macroscopic fission barrier). We propose: cap(subcritical l ) = cap for E ≤ Bo cap(subcritical l ) = cap(E=Bo)*Bo/Ec.m. for E > Bo

 P(survive) – Statistical model (Monte Carlo method) Partial widths for emission of light particles – Weisskopf formula where: Upper limit of the final-state excitation energy after emission of a particle i i – cross section for the production of the compound nucleus in the inverse process mi, si , εi - mass, spin and kinetic energy of the emitted particle ρ, ρi – level densities of the parent and daughter nuclei The fission width (transition state method), E*< 40 MeV Upper limit of the thermal excitation energy at the saddle

The level density is calculated using the Fermi-gas-model formula Shell effects included as proposed by Ignatyuk (A.V. Ignatyuk et al., Sov. J. Nucl. Phys. 29 (1975) 255) where: U - excitation energy, Ed - damping parameter , – shell correction energy, δshell (g.s.) (Möller et al., At. Data Nucl. Data Tables 59 (1995) 185), δshell(saddle)≈ 0 (W. Reisdorf, Z. Phys. A. – Atoms and Nuclei 300 (1981) 227) Bs , Bk ( W.D. Myers and W.J. Świątecki, Ann. Phys. 84 (1974) 186)

„Experimental” determination of fusion hindrance P(fusion) = σexp.(synthesis)/(σ(capture)  P(survival)) Data - 48Ca……70Zn + 208Pb, 209Bi GSI, Riken Lines - calculations using Smoluchowski diffusion equation

Smoluchowski Diffusion Equation Viscosity of fluid Temperature Driving force W(x,t) = probability to find Brownian particle at position x at time t Exact solution in a parabolic potential V(x) = -bx2/2 is a sliding, swelling Gaussian. P(fusion) = fraction of Gaussian captured inside the barrier as t→∞ P(fusion) = ½(1-erf√B/T) B = bx02/2 if x0 ≥ 0 (injection point), saddle injection point W.J. Świątecki, K. Siwek-Wilczyńska, J. Wilczyński Acta Phys. Pol. B34 (2003)2049, IJMP E13 (2004) 261, Phys.Rev.C71 (2005) 014602

26Mg + 248Cm →274-xnHs, 58Fe+208Pb →266-xnHs, 136Xe+136Xe →272-xnHs Test of P(fusion) as a function of entrance channel asymmetry and excitation energy Calculations for Z=108 (different mass asymmetries): 26Mg + 248Cm →274-xnHs, 58Fe+208Pb →266-xnHs, 136Xe+136Xe →272-xnHs  - Ch. Düllmann et al. Nature 418 (2002) 859, A. Türler et al. Eur. Phys. J. A17 (2003) 505 S. Hofmann, Rep. Prog. Phys. 61 (1998) 639; and private communication

136Xe + 136Xe → 272Hs experiment underway at Dubna

Summary: SHE production cross sections (synthesis) = (capture) × P(fusion) × P(survive) We have well tested tools for calculating capture cross sections (capture) and statistical decay of very heavy nuclei P(survive). For P(fusion) we use a simple model based on the Smoluchowski diffusion equation. This model works quite well for cold fusion reactions. It is essential to test predictions of P(fusion) for hot fusion reactions and more symmetric systems which probably will be used in attempts to synthesize new SHE (Z=120 and beyond), therefore comparison of Mg+Cm, Fe+Pb and Xe+Xe reactions is very important. Kazimierz, September 27- October 1, 2006