L.P. Csernai

1. Bergen Computational Physics Lab. L.P. Csernai BCPL Presentation -Csernai

2. Founding BCPL • 1999, Joint application by the Theoretical and Computational Physics Section and the Para//ab High Performance Computing Lab to EU for establishing a Research Infrastructure • Basis: Theoretical Reaction Modeling Capacity lags behind experimental resources (CERN, BNL, FNAL) hindering research advance • 2000, The EC supports BCPL as one of the 11 new Research Infrastructures! • 2001, EC awards 2nd RI grant to BCPL for fp5 BCPL Presentation -Csernai

3. € 813 000.- BCPL Presentation -Csernai (w/ MCTS)

4. ParallabUnifob BCPL Presentation -Csernai

5. Spring 2002: 30 visitors Since 2000: 44 Research Projects  100 visitors BCPL Presentation -Csernai

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8. Extension Proposal to EU, February 2001 BCPL Presentation -Csernai

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12. Highlights of BCPL achievements in 2001 Up to now BCPL has accepted 44 European projects for support from the beginning of yr. 2000. Near to 100 researchers visited BCPL. The capacity to receive researchers from the EU was increased by 30% (extra offices and workstations) compared to the one offered in the contract in the beginning of 2001. Although we did not receive additional financing from the EU to cover the excess demand, we accommodate 10-20% more visitors, than the contract allows, so we might run out of EU financing before the end of the contract period. In this report only a small fraction of the projects can be mentioned with important and recent results. The projects are grouped in thematic classes, as some of them are strongly related. BCPL Presentation -Csernai

13. NUCLEAR WASTE MANAGEMENT In the project "Transmutation of Heavy Nuclei" (project no. 3) from Calabria, Italy, led by L. Jenkovszky has completed its activity. It made an important step forward in "burning" radioactive nuclear waste to short lived and non-radioactive isotopes. Several core configurations were tested on our supercomputer, exploiting parallel processing. As a side effect with come core configurations 1000 times the invested energy could be recovered from the forced decay of radioactive waste nuclei. Another project, addressing topics related to nuclear waste, "Optimization of the Th-U Fuel Cycle for Molten-Salt Reactor" (project no. 30) from CEA, Saclay, France led by D. Ridikas, worked also on optimization of reactor core and fuel configurations. The aim of the project was to check the advantages of parallel processing in these Monte-Carlo codes. The project was successful, most codes could be converted by using local help, and most test runs completed successfully. BCPL Presentation -Csernai

14. SUBATOMIC REACTIONS Project no.7 & 20 "Event Generator for A+A Collisions at RHIC" from Ins. fuer Theoretische Phys., Uni. Frankfurt, Gremany led by M. Gorenstein had the ambitious goal to unify or match parton cascade, hydrodynamic and hadron cascade models for the description of A+A reactions. At the present stage physical assumptions on how to match different models were tested on the computer, to see what are the consequences of different assumptions andwhich can be realized in a computational model at all. Most assumptions lead to excessive computational task, and it is not trivial to find an accurate but computationally well realizable model. BCPL Presentation -Csernai

15. Heavy Ion Reactions at CERN-SPS Project: BCPL07 (Univ. of Frankfurt): Pb+Pb 160 GeV / nucleon, UrQMD model [Stöcker] BCPL Presentation -Csernai

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18. Project no. 29 "Hadronization and Freeze Out in Fluid Dynamics" from Uni. Lisbon, Portugal, led by V.K. Magas, had similar aim of coupling different modules of reaction models. The model was successful in working out the initial stage and its coupling to the CFD module. The publication reporting this work is submitted to Phys. Rev. D for publication already. The final module and the problem of Entropy production at this stage is still under intensive study. Project no. 16 "Strangeness production in heavy ion collisions" from Univ. of Oulu, Finland led by A. Keranen, works exactly on the same part of the problem. A highly parallelized hadronization code was worked out, which can be used in connection with a preceding CFD module. Several publications are expected soon based on these results, and this will lead to the evaluation of measurable hadron data in a detailed and accurate reaction model. A specific problem related to the same topic is studied in project no. 15 "Lambda (1520) production in NN collisions" from Uni. Marburg, Germany led by F. Puehlhofer. This particle has the same energetic properties as most other hadrons but its formation cross section is much smaller. Consequently it can make a difference between coalescence type of reaction models and thermal equilibrium models. The project works intensively on evaluating the consequences of the different model assumptions in different reaction models and compare the model results to the experimental data measured by their collaboration. This project illustrates one of the tightest collaborations between theory and experiment. BCPL Presentation -Csernai

19. 3-dim Hydro for RHIC Energies Au+Au ECM=65 GeV/nucl. b=0.1 bmax Aσ=0.08 => σ~10 GeV/fm n / n0 [ 1 ]e [ GeV / fm3 ] . . T= 0.0 fm/c nmax = 8.67 emax=32.46 GeV / fm3 Lx,y= 1.45 fm Lz=0.145 fm Bergen - Frankfurt - Los Alamos Nat. Lab. [Strottman] BCPL Presentation -Csernai

20. 3-dim Hydro for RHIC Energies Au+Au ECM=65 GeV/nucl. b=0.1 bmax Aσ=0.08 => σ~10 GeV/fm n / n0 [ 1 ]e [ GeV / fm3 ] . . T=1.9 fm/c nmax = 8.66 emax= 31.82 GeV / fm3 Lx,y= 1.45 fm Lz=0.145 fm BCPL Presentation -Csernai

21. 3-dim Hydro for RHIC Energies Au+Au ECM=65 GeV/nucl. b=0.1 bmax Aσ=0.08 => σ~10 GeV/fm n / n0 [ 1 ]e [ GeV / fm3 ] . . . T= 3.8 fm/c nmax = 7.77 emax= 27.22 GeV / fm3 Lx,y= 1.45 fm Lz=0.145 fm BCPL Presentation -Csernai

22. 3-dim Hydro for RHIC Energies Au+Au ECM=65 GeV/nucl. b=0.1 bmax Aσ=0.08 => σ~10 GeV/fm n / n0 [ 1 ]e [ GeV / fm3 ] . . T= 5.7 fm/c nmax = 6.36 emax= 26.31 GeV / fm3 Lx,y= 1.45 fm Lz=0.145 fm BCPL Presentation -Csernai

23. 3-dim Hydro for RHIC Energies Au+Au ECM=65 GeV/nucl. b=0.1 bmax Aσ=0.08 => σ~10 GeV/fm n / n0 [ 1 ]e [ GeV / fm3 ] . . T= 7.6 fm/c nmax = 5.22 emax= 37.16 GeV / fm3 Lx,y= 1.45 fm Lz=0.145 fm BCPL Presentation -Csernai

24. 3-dim Hydro for RHIC Energies Au+Au ECM=65 GeV/nucl. b=0.1 bmax Aσ=0.08 => σ~10 GeV/fm n / n0 [ 1 ]e [ GeV / fm3 ] . . T= 9.5 fm/c nmax = 4.45 emax= 32.86 GeV / fm3 Lx,y= 1.45 fm Lz=0.145 fm BCPL Presentation -Csernai

25. SUBATOMIC REACTIONS and ASTROPHYSICS Project no. 6 "Internal structure of neutron stars", from Opava, Czech Republic, led by Z. Stuchlik, studied of the consequences of QGP formation, as these influence the properties of neutron stars. Going beyond usual simplified studies, the group numerically evaluated the properties of rotating compact stars and their dependence on the QGP Equation of State. This way the astrophysical and accelerator studies can mutually complement each other for better understanding the high energy properties of matter. BCPL Presentation -Csernai

26. Project 42: Opava, CZ [Z.Stuchlik,S.Hledik] Cooling of extremely compact stars BCPL Presentation -Csernai

27. Radiation damage in solids [ Project: BCPL09] TU Darmstadt [Balogh] BCPL Presentation -Csernai

28. Project: BCPL09 BCPL Presentation -Csernai

29. ATOMIC and STATISTICAL PHYSICS Project no. 33: Dynamics of Atomic Bose Condensates, from Belfast, UK, led by J.F. McCann, aims for developing efficient high performance codes for modeling ultra-cold weakly interacting gases in a time dependent Hartree equation approach. The group developed a new method for studying complex deformation dynamics in irregular trap shapes such as asymmetric ellipsoids. The findings of this work are prepared for publication in Phys. Review. In addition the group has identified gyroscopic precession of vortex lines in ellipsoidal traps. This finding is now under further study. BCPL Presentation -Csernai

30. Dynamics of Atomic Bose Condensates,BCPL33 [McCann, Belfast] BCPL Presentation -Csernai

31. Belfast, BCPL33 BCPL Presentation -Csernai

32. Project no. 13 "Fluctuations and correlations - - analogies between fully developed turbulence and relativistic heavy-ion collisions" from TU Dresden, Germany lead by M. Greiner, studied FD similarities on different scales, reaching interesting and novel observations. The results are published in Phys. Lett. A and cond-mat/0106347. Project no. 27: Cusp Conditions on Wavelet Density Operators, from TU of Budapest, Hungary, led by J. Pipek, has found superstructures in electron density distributions in some mesoscopic systems. These superstructures are detected by calculating the structural entropy of distributions. These calculations have required massive computing power. BCPL Presentation -Csernai

33. Example for scaling J. Pipek pr. # 27: s0(r)s1(r) Daubechies 4 scaling function BCPL Presentation -Csernai

34. Iterative inclusion of details into rough scaled distributions The animation is the reverse play of the following process: A two-dimensional wavelet transform (Mallat's pyramidal algorithm, 1989) is applied to the source image, resulting in a smoothed version of the original that can be further attacked in exactly the same way as the original image to obtain the wavelet coefficients at the second highest resolution level. This process repeats over and over. BCPL Presentation -Csernai

35. Hordaland District Government – Regional Industry • Rolls-Royce Marine AS – Ulstein Turbine AS • Rogaland Forskning – Bergen: Multi-phase flow • Naturgas West / Shell Int. – Techn. Applications: Fuel cells • Rubitech AS: Dypvannsteknologi, Hydroacoustics • Naturgas West: Fluidized beds BCPL Presentation -Csernai

36. Future Plans: Hordaland Fylkeskommune - UiBed BCPL Presentation -Csernai

37. The Eurodyn’s Norwegian Heritage... • Mid 1960s, Kongsberg’s KG2 BCPL Presentation -Csernai

38. The Eurodyn’s Norwegian Heritage... • 21st Century, Eurodyn’s dual entry compressor and radial turbine • Unique • all radial technology gas generator • not an aero-derivative BCPL Presentation -Csernai

39. CONCLUSIONS The selected 10 projects give a taste of the variability of BCPL's research projects. The other 3/4th of the projects not mentioned in this brief report are similarly important and effective. Most projects were fully successful. In case of two projects we have registered problems due to the not perfect human assistance. (The researchers of these projects were in Bergen during the Easter period last year where most of the BCPL and Parallab staff is on vacation.) To, improve human assistance particularly in Computational Physics, Parallab employed in full position from Jan. 1, 2001 a Ph.D. Physicist, who also strengthens BCPL staff of project hosts. We hope this will further improve our service to EU users. This also indicates that human help and assistance is crucial in the operation of a Research Infrastructure, so BCPL puts maximum emphasis on this. The offered computational power to EU-RI user groups is increased by a factor of 12.8 from the beginning of 2002 by installing an IBM e-server supercomputer (For the same access charge to the EU as before!). At the time of the installation it was the 6th most powerful supercomputer in Europe. Bergen, Feb. 28, 2002 BCPL Presentation -Csernai