Presentation is loading. Please wait.

Presentation is loading. Please wait.

Relative kinetic energy correction to fission barriers 1. Motivation 2. Results for A=70-100 systems 3. A cluster model perspective 4. Prescription based.

Published by Modified over 8 years ago

Similar presentations

Presentation on theme: "Relative kinetic energy correction to fission barriers 1. Motivation 2. Results for A=70-100 systems 3. A cluster model perspective 4. Prescription based."— Presentation transcript:

1 Relative kinetic energy correction to fission barriers 1. Motivation 2. Results for A=70-100 systems 3. A cluster model perspective 4. Prescription based on w.f. localization & some results 5. Conclusions

2

3 Nucleus A=100, E=T intr+V, T intr = T- T cm 100 nucleons, T intr = 0 A A relative kinetic energy problem 2 nuclei A=50, T intr(50+50)= T intr (100) – T rel T rel = T cm1 + T cm2 – T cm(1+2)

4 Within HF: Asymptotically: The last term is T rel and should be subtracted to have a correct barrier for fusion, J.F. Berger and D. Gogny, N.P. A 333 (1980) 302 Fission barriers: In macro-micro mathods, a deformation dependent Wigner term was introduced to improve agreement with the data for lighter systems, W.D. Myers and W.J. Swiatecki, N.P. A 612, 249 (1997) Problems with a transition from one- to two-piece systems are spelled out in: P. Moller, A.J. Sierk and A. Iwamoto, P.R.L. 92, 072501 (2004)

5 Our code assumes two symmetry planes, so we can study tip- and side collisions. The HF (BCS) problem is solved on a spatial mesh. Static fusion barrier (l=0): V(R) = E[1+2](R)+B1+B2, (1) Static fission barrier: V(R) = E[1+2](R)+B(1+2), (2) where B1&B2&B(1+2) positive binding energies and E[1+2] - negative HF(BCS) energy of the combined system. We use Skyrme forces SkM* and SLy6, include no pairing, or delta-pairing with cut-off, a la M. Bender et al., Eur. Phys. J. A 8, 59 (2000). The latter ensures smooth transition of pairing from a 2- to 1-piece shape.

6 To have V=0 at infinity, one has to replace: V by V-T rel, where the relative kinetic energy at infinity is: (A2*t1+A1*t2)/(A1+A2), with t1 & t2 c.m. kinetic energies of the fragments. Example: for the merging fragments 48Ca and 208Pb one has with SLy6: Ecm(48Ca)=8.2 MeV, Ecm(208Pb)=5.9 MeV, Ecm(256No)=5.7 MeV, So, asymptotically, one has to subtract 8.4 MeV from (1) or (2). Various forces have specific prescriptions to correct for the c.m. motion of the system: -one-body part of P^2/2Am – amounts to 16.5-18.5 MeV (like SkM*) -total P^2/2Am (with two body part) – amounts to 5-8 MeV (like SLy6)

7 This subtraction is clear for light fusing systems, with barriers at nearly separated shapes. For heavier systems the barriers correspond to some density overlap, so the subtraction should be partial. When two fragments merge into one, their relative kinetic energy becomes a part of the potential energy. No exact treatment of this problem is known. A simple choice for relatively light systems: - apply subtraction of the symptotic term to obtain the fusion and fission barrier

8 P.R. C 74, 051601(R) (2006)

9

10 [16]: T.S.Fan et al.., N.P.A 679, 121 (2000) [8]: K.X. Jing et al., N.P. A 645, 203 (2000)

11 48 Ca + 48 Ca 48 Ca + 208 Pb

12 Dispersion of particle number in the k-th orbital:

13 Gradual subtraction of E kin rel – no exact prescription available

14 48 Ca + 244 Pu : Z=114, A=292 Q =225 b, For SkM*: E constr – E neck = 25.7 MeV vs 15 MeV

15 Can one learn anything from the theory of light nuclei? R.G. Lovas et al., Phys. Rep. 294, 265 (1998) Overcomplete basis:

16 No prescription for T rel.

17

18 B corr = 4.2 MeV

19 Q=300 b

20 At Q=200 b, T rel = 1.9 MeV

21 Q=125 b Q=200 b

22

Download ppt "Relative kinetic energy correction to fission barriers 1. Motivation 2. Results for A=70-100 systems 3. A cluster model perspective 4. Prescription based."

Similar presentations

Anatoli Afanasjev Mississippi State University Recent progress in the study of fission barriers in covariant density functional theory. 1. Motivation 2.

Anatoli Afanasjev Mississippi State University Recent progress in the study of fission barriers in covariant density functional theory. 1. Motivation 2.
7: Atomic and Nuclear Physics 7.3 Nuclear reactions, fission and fusion.

7: Atomic and Nuclear Physics 7.3 Nuclear reactions, fission and fusion.
Pavel Stránský 29 th August 2011 W HAT DRIVES NUCLEI TO BE PROLATE? Instituto de Ciencias Nucleares, Universidad Nacional Autónoma de México Alejandro.

Pavel Stránský 29 th August 2011 W HAT DRIVES NUCLEI TO BE PROLATE? Instituto de Ciencias Nucleares, Universidad Nacional Autónoma de México Alejandro.
Microscopic time-dependent analysis of neutrons transfers at low-energy nuclear reactions with spherical and deformed nuclei V.V. Samarin.

Microscopic time-dependent analysis of neutrons transfers at low-energy nuclear reactions with spherical and deformed nuclei V.V. Samarin.
Binding Energy Binding Energy per Nucleon. Binding Energy The term binding energy is used to indicate the energy that would be required to form an atom.

Binding Energy Binding Energy per Nucleon. Binding Energy The term binding energy is used to indicate the energy that would be required to form an atom.
Nuclear Binding Energy

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

The Dynamical Deformation in Heavy Ion Collisions Junqing Li Institute of Modern Physics, CAS School of Nuclear Science and Technology, Lanzhou University.
Kazimierz 200 9 What is the best way to synthesize the element Z=120 ? K. Siwek-Wilczyńska, J. Wilczyński, T. Cap.

Kazimierz What is the best way to synthesize the element Z=120 ? K. Siwek-Wilczyńska, J. Wilczyński, T. Cap.
Forces for extensions of mean-field PhD Thesis Marlène Assié Denis Lacroix (LPC Caen), Jean-Antoine Scarpaci (IPN Orsay)  Extensions of mean-field ? 

Forces for extensions of mean-field PhD Thesis Marlène Assié Denis Lacroix (LPC Caen), Jean-Antoine Scarpaci (IPN Orsay)  Extensions of mean-field ? 
9/28/2006 19:01 (00) PAIRING PROPERTIES OF SUPERHEAVY NUCLEI A. Staszczak, J. Dobaczewski and W. Nazarewicz (KFT UMCS) (IFT UW) (ORNL & UT)

9/28/ :01 (00) PAIRING PROPERTIES OF SUPERHEAVY NUCLEI A. Staszczak, J. Dobaczewski and W. Nazarewicz (KFT UMCS) (IFT UW) (ORNL & UT)
Fission Barriers in Skyrme-HFB Approach LORW group 14 th Nuclear Physics Workshop Marie & Pierre Curie Kazimierz 2007.

Fission Barriers in Skyrme-HFB Approach LORW group 14 th Nuclear Physics Workshop "Marie & Pierre Curie" Kazimierz 2007.
9-10-2008 21:12 (00) Below-barrier paths: multimodal fission & doughnut nuclei A. Staszczak (UMCS, Lublin) FIDIPRO-UNEDF collaboration meeting on nuclear.

:12 (00) Below-barrier paths: multimodal fission & doughnut nuclei A. Staszczak (UMCS, Lublin) FIDIPRO-UNEDF collaboration meeting on nuclear.
Center of Mass. Motion of the Center of Mass The center of mass of a system moves as if all of the mass of the system were concentrated at that point.

Center of Mass. Motion of the Center of Mass The center of mass of a system moves as if all of the mass of the system were concentrated at that point.
1 Role of the nuclear shell structure and orientation angles of deformed reactants in complete fusion Joint Institute for Nuclear Research Flerov Laboratory.

1 Role of the nuclear shell structure and orientation angles of deformed reactants in complete fusion Joint Institute for Nuclear Research Flerov Laboratory.
Momentum For N particles: Why bother introducing one more definition? Most general form of the Newton’s law: Valid when mass is changing Valid in relativistic.

Momentum For N particles: Why bother introducing one more definition? Most general form of the Newton’s law: Valid when mass is changing Valid in relativistic.
Fission fragment properties at scission:

Fission fragment properties at scission:
SH nuclei – structure, limits of stability & high-K ground-states/isomers 1.Equilibrium shapes 2.Fission barriers 3.Q alpha of Z=98-126 ( with odd and.

SH nuclei – structure, limits of stability & high-K ground-states/isomers 1.Equilibrium shapes 2.Fission barriers 3.Q alpha of Z= ( with odd and.
 What are the appropriate degrees of freedom for describing fission of heavy nuclei (171 ≤ A ≤ 330)?  Fission barrier heights for 5239 nuclides between.

 What are the appropriate degrees of freedom for describing fission of heavy nuclei (171 ≤ A ≤ 330)?  Fission barrier heights for 5239 nuclides between.
Instructor: Dr. Alexey Belyanin Office: MIST 426 Office Phone: (979) 845-7785 Office.

Instructor: Dr. Alexey Belyanin Office: MIST 426 Office Phone: (979) Office.
Physics Nuclear Physics: Binding Energy Science and Mathematics Education Research Group Supported by UBC Teaching and Learning Enhancement Fund 2012-2014.

Physics Nuclear Physics: Binding Energy Science and Mathematics Education Research Group Supported by UBC Teaching and Learning Enhancement Fund

Similar presentations

Ads by Google