The continuum time-dependent Hartree-Fock method for Giant Resonances C. I Pardi & P. D. Stevenson Department of Physics University of Surrey Guildford Surrey United Kingdom
Background to the problem Starting from a time-dependent mean field, in the form of the self-consistent TDHF method, is a powerful way to tackle many kinds of collective motion: Giant resonances Deep-inelastic collisions Fusion Fission (maybe) For giant resonances, the low-amplitude TDHF limit corresponds to RPA Giant resonances are in the continuum and require treatment of the continuum no matter the basic theoretical approach Recent review on TDHF & related methods: Cédric Simenel, Eur. Phys. J. A 48, 152 (2012)
Why Giant Monopole Resonances, briefly? Giant Monopole resonances are radial excitations, with the T=0 oscillation being termed the “breathing mode” Their properties correlate strongly with the nuclear compressibility, and hence important in determining the Equation of State More prosaically, their radial nature means that, for a nucleus which is spherical in its ground state, it remains spherical for all time during excitation and decay ⇒ Good simple starting point when developing new theoretical methods. The spherically-symmetric case can also be calculated by quasi-exact methods, for comparison IVGDR Picture: Harakeh and van der Woude, Giant Resonances, OUP
Experimental strength Y.-W. Lui, H. L. Clark, and D. H. Youngblood, Phys. Rev. C 64, 064308 (2001)
Reflection
Box boundary conditions
Strength Functions
Absorbing potentials Can add extra spatial points, and place an imaginary absorbing potential in it. Can be costly to get a sufficiently exact result. P.-G. Reinhard, P. D. Stevenson, D. Almehed, J. A. Maruhn and M. R. Strayer, Phys. Rev E 73, 036709 (2006) Much other work on absorbing boundaries in nuclear physics, esp by Nakatsukasa et al (e.g. Nakatsukasa and Yabana, EPJA25, 527 (2005)) <r^2>
Strength Functions with absorption Strength functions are particularly sensitive to the effects of reflection: P.-G. Reinhard, P. D. Stevenson, D. Almehed, J. A. Maruhn and M. R. Strayer, Phys. Rev E 73, 036709 (2006)
Laplace Transform Method We implemented an exact solution to the problem using a Laplace transform of the TDHF equation. It requires finding analytic solutions for the transformed wave function in a region exterior to the nucleus and transforming back to get the time-dependent wave function Some lengthy manipulation gives the neutron kernel as: Full details in Pardi & Stevenson, PRC87, 014330 (2013) Note k=sqrt(2is) Where R is the spatial coordinate of the edge of the box, and and
Inverse Transform This kernel is represented in partial fractions, which enables the inverse transform to be performed analytically, giving In terms of a time-like coordinate 𝜏. This must be integrated from t=0 to the current simulation time to recover the history of all outgoing flux at the boundary. This exact boundary condition is non-local in time, which incurs a computational cost. Proton states require a different kernel thanks to the long-range Coulomb potential. We use a numerical approximation to the kernel to enable us to analytically inverse-transform it.
Results Isovector Monopole response in O-16 with simplified Skyrme force (30 fm box)
Strengths 16O 40Ca artefact-free strengths Simple t0-t3 force gives e.g. incorrect ordering of IS vs IV resp: Full Skyrme force needed
Summary & Outlook We have implemented a formally exact boundary condition for time-dependent problems The application so far is to giant monopole resonances with a simplified Skyrme force Strength functions can be practically calculated to arbitrary energy resolution. In the short-term future we will extend to full Skyrme force Longer term plan is to make multipole expansion of nuclear densities. Implementation in axial or 3D code probably prohibitive at present.
Acknowledgements This work funded by the UK STFC Performed in part in collaboration with K Xu (NAG, Oxford)