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Молодежная Школа - Семинар «Вклад молодых ученых России в проект FAIR»

ИНФОРМАЦИОННОЕ СООБЩЕНИЕ №1

6 - 7 апреля 2010 года Исследовательский Центр ФАИР - Россия (ИЦФР) приглашает студентов, аспирантов и молодых ученых принять участие в семинаре, посвященном разработкам и исследованиям молодых российских специалистов, проводимых в рамках проекта FAIR.

На семинаре могут быть представлены работы, проводимые по темам, указанным в приложении 1. Названия докладов и аннотации (не более 1 страницы) необходимо направить до 1 апреля 2010 г. (включительно) по электронной почте на адрес This e-mail address is being protected from spambots. You need JavaScript enabled to view it. . Время, отводимое для приглашенного доклада - 20 мин., включая обсуждения. Аннотации докладов будут опубликованы на сайте ИЦФР. Рабочий язык – английский.

Семинары будут проходить по адресу г. Москва, ул. Б. Черемушкинская, 25, ФГУП «ГНЦ РФ – ИТЭФ», корпус №40.

Транспортные расходы и расходы на проживание в Москве приглашенных участников Семинара (Гостиница ИТЭФ) будут оплачены ИЦФР (в случае подачи заявки до 22 марта 2010 года).

Оргкомитет семинара

Директор ИЦФР - Проф. Д.ф.-м.н. член-корр. РАН Б.Ю. Шарков

Директор ИЦФР – Проф . Х. Гутброд

Зам. Директора ИЦФР – к.ф.-м.н. А.Д. Фертман

Ответственный секретарь ИЦФР – Екатерина Гурьева





Приложение 1

Enclosure 1 List of topics for FRRC fellowship applications

  • 1. High intensity heavy ion and hadron synchrotrons . Investigation of space charge effects, dynamic vacuum, limiting beam intensities.
  • 2. Investigation of heavy ion beam losses and radiation hardness and life-time of the accelerator ring elements.
  • 3. Optimization of the accelerator lattice.
  • 4. Investigation of beam dynamics, optimal working points, necessary correction and corrector elements.
  • 5. Researches of RF acceleration and bunch compression regime.
  • 6. Investigation of heavy ion beam extraction from synchrotrons: efficiency, reliability, optimal schemes.
  • 7. Storage rings and colliding beams. Electron-Ion Collider - investigation of nonlinear effects, final focus, beam-beam interaction and detector background. AIC –Antiproton-Ion Collider - investigation of final focus, beam-beam interaction, minimal of EIC ring reconstruction for AIC mode operation. Polarized proton-antiproton colliding beams in HESR. - investigation of antiproton polarization, polarized proton acceleration at SIS18, Siberian snakes for polarization control.
  • 8. Investigation of heavy ion beam cooling (problems of electron and stochastic methods). Electron cooling for NESR, AIC, HESR.
  • 9. Research & Development of superconducting magnet technology: fast-ramped, fast-cycling magnets for the magnetic field range of 1.5 – 4.5 T and the field ramp from 4 to 1 T/s. Research & Development of specific magnets for SIS100, SIS300, SSFRS (superconducting dipole and quadrupole magnets and septum-magnet with magnetic field up to 30 T).
  • 10. Magnet design: including optimization of 2D and 3D geometries, mechanical and thermal calculations, cryogenic calculations etc.
  • 11. Research & Development of superconducting cables and helium cooling schemes, heat load and heat transfer.
  • 12. R&D of theoretical basis for experiments in atomic physics, nuclear structure-, heavy ion-, nuclear astrophysics, hadron physics and accelerator physics in FAIR international collaborations.
    • 12.1 Physics of quark-gluon plasma;
    • 12.2 Physics of high-energy density in matter;
    • 12.3 Ion and laser beam interaction with matter;
    • 12.4 Beam and accelerator physics;
    • 12.5 Specific structure of the drip-line nuclei;
    • 12.6 Mechanisms of nuclear reactions with the drip-line nuclei;
    • 12.7 Scattering of electrons on the exotic nuclei;
    • 12.8 The equation of state for an asymmetric nuclear matter;
    • 12.9 Exotic nuclei, astrophysics and nuclear synthesis in the Universe;
    • 12.10 Prerequisites for tests of fundamental theories and determination of fundamental constants, nuclear magnetic moments, and nuclear charge raddii at the FAIR facilities.
    • 12.11 Study of relativistic quantum dynamics in strong fields, kinetics of stopping, charge exchange and excitation of fast highly charged ions in matter for the FAIR experiments.
    • 12.12 Study of radiative properties of multicharged ions in storage rings and dense matter for FAIR facilities: anomalious radiative recombination and radiative cascades, coherent polarization radiation.
    • 12.13 Glueball spectrum and search for other exotic states.
    • 12.14 Spectroscopy of charmonium, new heavy-light mesons, and heavy barions.
    • 12.15 Physics of hypernuclei and charmnuclei.
  • 13.New generation of installations and detectors for experiments in atomic physics, nuclear structure-, heavy ion-, nuclear astrophysics and hadron physics in international collaborations at FAIR.
    • 13.1.1. Development of CBM detector concept. Preparation and writing of the technical design report (TDR).
    • 13.1.2. Work on prototype of CBM subdetectors, read-out electronics and DAQ.
    • 13.1.3. Development of CBM subdetectors concept. Preparing technical documentation.
    • 13.1.4. Manufacturing of subdetectors and read-out electronics. Creation of the mass production quality control system. Commissioning of subsystems in CBM detector.
    • 13.1.5. Development and manufacturing of superconducting dipole magnet for CBM detector.
    • 13.2.1. Research and development of electromagnetic calorimeters for PANDA (PWO, Shashlyk and avalanche photodiods of large area);
    • 13.2.2. Research and development of tracking and particle identification detectors for PANDA (muon system, quartz radiators, solenoid, time-of –flight system, silicon pixel vertex detector).
    • 13.2.3. Optimization of PANDA sub-detectors using MC simulation.
    • 13.2.4. Research and development of Pellet Target for PANDA.
    • 13.3.1. Development of NUSTAR physics program (projects: R3B, EXL, ELISe, AIC, ILIMA and MATS), detailed modeling of the chosen experiments, an estimation of experimental opportunities of setup, possible changes in the experimental installation.
    • 13.3.2. Research and development of Super FRS scientific and technical details.
    • 13.3.3. Electron spectrometer for the e-A collider.
    • 13.3.4. R&D and manufacturing of coordinate detector systems (silicon micro-strip detectors with the large area; parallel-plate avalanche chambers; resistive-plate chambers for the neutron detectors; vertical drifts chambers; detector systems on the basis of straw-tubes).
    • 13.3.5. R&D and manufacturing of details for scintillation detector systems (blocks of scintillators for γ-spectrometers on the basis of CsI (Tl), BaF2 and PbWO4 crystals; larger-area avalanche photo diodes for reading the information from scintillators; the mechanical systems fixing components of the γ- spectrometers; systems for the temperature stabilization of γ – spectrometers).
    • 13.4. Research, development and design of FLAIR/SPARC experimental area (Low-energy Storage Ring (LSR), Ultralow energy Storage Ring (USR), Positron Cooler Storage Ring (PCSR) and the ion trap facility (HITRAP)).
  • 14.High-energy density in matter with highly compressed heavy-ion beam bunches in unique combination with powerful lasers.
    • 14.1.Research, development, design and manufacturing of beam line details for plasma physics experiments;
    • 14.2.Research and development of novel diagnostic methods for measuring the basic physical parameters of the HED matter under the specific conditions of ion-beam heating.
    • 14.3.Development, design and manufacturing of the rf-beam rotator (wobbler) for the LAPLAS experiment;
    • 14.4.Research, development and construction of the ion/proton radiography system for high-energy density in matter experiments;
    • 14.5.Design and construction of vacuum target chambers for High-energy density in matter experiments;
    • 14.6.Design and construction of the cryogenic target preparation setup for the plasma physic experiments;
  • 15.Development of software packages for simulation, reconstruction and data analysis for FAIR accelerators and experimental collaborations (EC).
  • 16.Support and development computing resources of Russian institutes participated in FAIR EC. Participation in the development of GRID for FAIR EC purposes;
  • 17.Radiation safety aspects at FAIR.
    • 17.1.Characterization of radiation from selected components of the beam line of FAIR accelerators: production rates of radioactive nuclides;
    • 17.2.Long time prediction of radioactive inventory around the critical points of beam transport system;
    • 17.3.Characterization of the hazard from secondary neutrons for intense heavy ion beam facilities;
    • 17.4.Optimization of radiation shielding and design of radioactivity monitoring systems for FAIR accelerators and experimental collaborations.
  • 18.Technical developments and applied research with ion beams for materials science, medicine and biology.