ap-3-10.dvi Acta Polytechnica Vol. 50 No. 3/2010 The Science Policy of the Joint Institute for Nuclear Research A. Sissakian Dear Colleagues, It is great honor for me to participate in this confer- ence, devoted to the 70th anniversary of the birth of the prominent Czech scientist Professor Jiří Niederle. Following the title ofmy talk, I’ll give youan intro- ductory presentation about JINR’s strategic develop- ment plans, starting with a very brief historical back- ground. The Joint Institute for NuclearResearch (JINR) is located in the MoscowRegion, inDubna, on the bank of the Volga river (120 km to the north of Moscow). The Institutewas established inMarch1956 througha convention signed by the Plenipotentiaries of the gov- ernments of the JINR Member States. The Institute was created in order to unify the intellectual and ma- terial potential of theMember States in order to study the fundamental properties of matter. Until the early 1990s, Dubna was a centre that unified the efforts of leading research groups in the nuclear sciences from the socialist countries and the Soviet Union. A new development stage in the history of the In- stitute has started in 1992. 18 independent states, including 9 republics of the former USSR, became its Member States. In addition, agreements at govern- mental level were signed for cooperation with 6 coun- tries –Germany,Hungary, Italy, theRepublic of South Africa, Serbia and, recently, with Egypt. It is well-known that the future is based on the past, and on traditions. JINR has a huge foundation based on three “pillars”: • great experience in nuclear physics research and the world-wide recognized traditions of its scien- tific schools • a large and unique park of basic facilities for fun- damental and applied research • the status of an international intergovernmental organization For over 50 years of JINR’s existence, first-class theoretical and experimental researchprogrammes im- plemented at JINR have led to a significant scientific output in fundamental nuclear science. More than 40 discoveries in nuclear physics, particle physics and condensedmatter physics havebeenmade in the JINR laboratories. In recognition of the achievements of JINR’s staff of researchers, in 1997 the International Committee for Pure and Applied Chemistry awarded the name “Dubnium” to element 105 of thePeriodicTable ofEl- ements. Among the latest bright results, I would like to mention the pioneering investigations of the chem- ical properties of the superheavy elements. The main governing body of the Institute is the Committee of Plenipotentiaries of theMember States’ Governments. The scientific policy is established and co-ordinated by the Scientific Council, whose mem- bers are prominent and well-known scientists from the Member States as well as from CERN, Germany, Greece, France, Italy, China, India and other coun- tries. Three Programme Advisory Committees for ParticlePhysics,NuclearPhysics andCondensedMat- ter Physics hold their meetings twice a year. There are seven Laboratories at JINR, each being comparable to a large research institution in terms of the scope of scientific activities. We also have a Uni- versity Centre, as well as several functional subdivi- sions and workshops. Present Scientific Policy The triad: fundamental research, innovation develop- ments and the educational programme – forms the strategic policy line of the Institute’s development. I would like to note that, along with the current 7-year programme of the Institute’s development for the years 2003–2009 (and now we are developing the next 7-year programme for the years 2010–2016),1 we have elaborated the programme of JINR’s strategic development (the so-called Road Map) for the next 10–12 years. This programme takes into account both theworld tendencies in scientificdevelopmentsand the interests of our Member States. Fundamental studies will remain as the general di- rection of JINR’s development. At the same time, spe- cial attention will be given to innovation activities, in particular to radiationmedicine, nanotechnologies and others. The innovative projects will be developed in close cooperationwith the Public-Private-Partnership in the framework of the Special Economic Zone in Dubna. The role of the educational programme will be further enhanced. The Road Map has determined three major re- searchdirectionsat JINR:high energyphysics, nuclear 1Approved in September 2009 by the JINR Scientific Council, and in November 2009 by the JINR Committee of Plenipotentiaries of the governments of the Member States 109 Acta Polytechnica Vol. 50 No. 3/2010 physics and condensed matter physics. As I have al- ready mentioned, the activities in these directions are implemented at our seven laboratories. Such disciplines as theory, network and comput- ing, as well as physics instrumentation and methods, training of the young generation are very important supporting activities for our basic research directions. Oneof thekeypoints of theRoadMap is thatJINR should develop its role as a world leader in certain re- searchdomains. Therefore, it is necessary to formulate the priority trends in the development of the Institute. To achieve this ambitious goal, we under- stand clearly that the whole experimental in- frastructure of the Institute, and first of all our basic facilities, must be completely upgraded. Such a programme will allow us to become a compet- itive scientific laboratory, attractive, first of all, for the Member States, for the countries with which we have tight and long-standing cooperation activities, e.g. Czechia, Hungary, Germany, France, Italy and other partners. While updating the Road Map we clearly see that the research niches for JINR, offered by our home fa- cilities, are the following: Heavy Ion Physics at high energies and at low energies, and condensed matter physics using nuclear-physics methods, including ra- diobiology studies. Now briefly about our large-scale facilities and our ambitious research projects. In Heavy Ion Physics at High Energies, the new flagship of the Institute and the highest priority project is the NICA/MPD (Nuclotron-Based Ion Col- lider fAcility andMultiPurposeDetector) with energy of 4–11 GeV in the nucleon-nucleon center-of-mass. This project is aimed at the study of hot and dense strongly interacting QCD matter and the search for a possible manifestation of mixed phase formation in heavy ion collisions, as well as studies on spin physics. This energy range is of great interest and impor- tance forunderstanding the evolutionof theEarlyUni- verse in the first milliseconds after the Big Bang, and the formationofneutronstarsaswell. Toachievethese physics goals on NICA, we have to accomplish several large technical tasks. First of all, upgradingof theNu- clotron itself, achieving itsprojectparametersby2010. This will be the first step towards the NICA collider facility. The next two steps deal with the design and construction of the heavy ion collider itself and the MultiPurpose Detector. The key advantage of the NICAproject is the sufficientlyhigh luminosity in the energyrange of 4–11GeV in thenucleon- nucleon center-of-mass (∼ 1027 cm−2sec−1 at 9 GeV). The NICA complex will comprise several acceler- ators and beam transfer channels. The design of the collider suggests two intersectionpoints, where the de- tectors are to be located. One of them, the MultiPur- pose Detector (MPD), is dedicated to Mixed Phase problem studies. One of the options for another de- tector is a Spin Physics Detector (SPD). Table 1: NICA general parameters Ring circumference 251.52 m Bρ max 45.0 T ·m Ion kinetic energy (Au79+) 1.0 ÷ 4.56 GeV/u Dipole field (max) 4.0 T Free space at interaction point (for detector) 9 m Beam crossing angle at interaction point 0 Vacuum 10−11 Torr Luminosity per one interaction point 0.75÷11 ·1026 cm−2 · s−1 The central goal of the heavy ion experimental studies is to explore the phase diagramof nuclearmat- ter. It is expected that it has at least two different phases: hadronic and quark-gluon phases, and they are separated by a first order phase transition at high baryon densities. In theplaneof temperature andbaryon-density the first order phase transition results in a finite width band of the coexistence region of these two phases, the so-calledmixed phase. We attracted the attention to this remarkable fact in the middle of 2005. Exploration of the mixed phase region is one of the goals of the future NICA/MPD and FAIR/CBM (Compressed Baryonic Matter) experiments, together with the low energy scan program at RHIC and the NA61 experiment at SPS. This region has not been adequately explored up to now. Among our external research activities I would like to mention two experiments with JINR’s most ac- tive participation. The first of these is the CERN NA48/2 experi- ment.Very large statistics of high performance data of charged kaon decays has been accumulated by this experiment at the CERN SPS. Two major parame- ters – a0 and a2 – of scattering lengths have been extracted with an unprecedented experimental precision of a few percent, allowing accurate tests of Chiral Perturbation theory predictions. This re- sultwas highlightedatCERNasan experimen- tal achievement in 2008. The other experiment deals with our activities at Fermilab. JINR physicists, together with their Amer- ican colleagues, performed a physical analysis in 2008 of the D0 experiment at the Tevatron, which led to the first observation of the Ωb baryon. This discov- ery was ranked among the ten most significant achievements in physics in 2008 by the Amer- 110 Acta Polytechnica Vol. 50 No. 3/2010 ican Physics Society, and we are again proud that JINR made a significant contribution to this analysis. JINR successfully completed all its obligations to the three LHC projects: ATLAS, ALICE and CMS. The total contribution of JINR to these projects, in- cluding LHC Damper, amounted to approximately 25 million Swiss francs. Concerning JINR-CERN col- laboration, I’d like to note that in accordance with our recent negotiations with the new CERN Director- General R. Heuer, our collaboration will be of high priority for both centres. Now we are preparing a re- newed version of the general Partnership Agreement to be signed at the beginning of 20102. As for nuclear physics (low and intermediate en- ergy heavy ion physics), I’d like to mention that we are proud that in the last decade JINR has become one of the leading scientific centres in the world in the synthesis of superheavy elements and physical and chemical investigations of these nuclei. Other priority topics in this domain are the structure and properties of neutron-rich light exotic nuclei, accelerator technol- ogy and broad applied research, including nanotech- nology. For the past 7-year period in a number of experi- ments performed with the use of the intense beam of 48Ca and actinide targets, 5 new elements and 34 new superheavy isotopes have been synthesized. These ex- periments have been carried out in wide collaboration with scientific centers in Russia and the USA. Chem- ical properties of elements 112–115 were established for the first time. In particular, it was shown that ele- ments 112 and 114 aremore volatile than their lighter homologues, due to relativistic effects in the electronic structure. So, a new branch of science really is presently developing at JINR – Relativistic Chemistry of Superheavy Elements. Neutrino physics is a traditional research topic for our Institute. One of the most fundamental studies in neutrino physics is the search for neutrinoless double betadecay. Very impressiveresultshavebeenobtained by the NEMO-3 Collaboration. At present the limit for neutrino mass established by this experiment is of the order of 1 eV. It is planned in 2009–2010 to go down by a factor of two in this limit. In 2011 the in- stallationof the SuperNEMOdetectorwill start. This new detector will provide sensitivity for the search for neutrinoless double beta decay below 0.1 eV in the neutrino mass. As for condensed matter physics’, I’d like to men- tion that JINR’s basic facility here is the IBR-2 fast pulsing reactor. It is included in theEuropean20-year strategic research programme with neutrons. The re- actor is now under an upgrade programme. In 2010, the practically new IBR-2M reactor will start up its operation. The main priorities in condensed matter physics in the next 7-year period deal with reliable operation at design parameters of the new IBR-2M reactor, the establishment of a complex of modern neutron spectrometers, realization of a full-scale cryogenic complex, as well as wide-ranging innovations includ- ing nanoscience. Special attention will be given to further development of the spectrometer complex of the IBR-2M reactor. The first priority projects in- clude the construction of the new DN-6 spectrometer for studies of microsamples, the GRAINS multifunc- tional reflectometer, and modernization of the spec- trometer complex for geophysical research. These fa- cilities will significantly expand the area of world-level researchat the IBR-2Mreactor. We expect a broad international user policy on this machine, as in the past, or even broader. The radiobiology studies at JINR are aimed at ob- taining fundamental results which will be principally important to general and cosmic radiobiology. Start- ing from 2009, our Laboratory of Radiobiology has conducted its research programme under the scientific and methodological supervision of the Section of Bio- logical Sciences of the Russian Academy of Sciences. It is important to take into our consideration that in this field of our activities we have to employ the huge scientific potential of the Joint Institute for the progress of this trend at the interface of biology, medicine and physics. Obviously, we have to ex- pect innovation breakthroughs exactly in this area during the next evolution cycle of civiliza- tion. The educational programme plays an important role in the JINR’s activities. In 1991 we established the JINRUniversityCentre and in 1994, togetherwith the Russian Academy of Natural Sciences, the Dubna International University. This provides good oppor- tunities for young scientists to get their postgradu- ate training, obtainPhDdegrees and receive advanced professional training using JINR’s experimental facili- ties. TheDubna InternationalAdvancedSchool onThe- oretical Physics came into operation in 2003. A few words about the innovation activities in our Institute. In 2005 the Russian Government adopted a resolution on the establishment of six Special Eco- nomic Zones (SEZ) in the territory of the Russian Federation. The status of a special economic zone of technological and innovative type was granted to four towns: Zelenograd,Dubna, St.PetersburgandTomsk. Themain specializations of the Dubna SEZ are re- lated to nuclear physics and IT technologies, including radiation medicine, safety systems, nanotechnologies and IT technologies. On18April 2008,President of theRussianFedera- tionDmitry Medvedev chaired a session of the Presid- iumof the StateCouncil inDubnawhichdiscussed the issue “Developmentof theNational InnovationSystem in the Russian Federation”. 2Agreement has been signed on 28 February 2010. 111 Acta Polytechnica Vol. 50 No. 3/2010 During his visit, PresidentD.Medvedev highly ap- preciated the results of JINR’s basic research and un- derlined the role of science in the innovation process. The President noted the importance of the future realization of two large-scale projects, proposed by JINR: the establishment in Dubna of a Centre for Radiation Medicine and of an International Inno- vation Centre for Nanotechnology. I would like to note that over the decades JINR has played the role of a cluster centre for its Mem- ber States, giving them an efficient way to be inte- grated into the European scientific society (for exam- ple CERN, INFN and others). We hope that the International Innovative Centre for Nanotechnology, which we are now creating, will also serve for the integration of European innovation activities. In particular, you know that in 2008 the European Institute for Innovation and Technology was estab- lished by the EuropeanUnion, with its General Head- quarters in Budapest, Hungary. We intend to include our Innovation Centre in its Knowledge and Innova- tion Communities (KIC) as a first step in the integra- tion process. I believe that our cooperation with the Member States will further serve our mutual interests and, un- doubtedly,will strengthen the scientific ties inbothba- sic and applied research andwill integrate our joint research into European science. Concluding, letme say a fewwords about coopera- tion activities between JINR and Czechia. The Czech Republic has always been one of the most active In- stitute Member States. It should be mentioned that Czech scientists have served as JINR Vice-Directors, Deputy Directors of the JINR laboratories, heads of departments and groups: V. Votruba, V. Petrzilka, C. Simane, I. Zvara and many others. Taking the opportunity, I would like to cordially congratulateProf. Cestmir Simane onhis forthcoming 90th birthday, and wish him good health and happi- ness. Today JINR conducts cooperation with 9 Czech scientific centres, 3 Universities and the company Vacuum-PRAGUE on 34 scientific topics in all JINR scientific trends. JINR’s main partners in the Czech Republic are: the Nuclear Physics Institute in Rez, Charles Univer- sity, the Czech Technical University, the Institute of Physics in Prague, the company Vacuum Prague, and many others. A ceremonial meeting dedicated to the 50th an- niversary of JINR was held on 24 January in Prague, in the building of Charles University, one of the oldest universities in Europe. Among the honorary guests present at the meet- ing were Prime Minister of the Czech Republic J. Paroubek, Plenipotentiary of the Russian Federa- tion to Czechia A. Fedotov, as well as representatives of Czech scientific, governmental and social organiza- tions. Prime Minister of Czechia J. Paroubek congratu- lated the audience on the 50th anniversary of JINR and noted the great role of the Dubna international physics centre in founding and developing nuclear physics in all countries – JINR Member States, in- cluding Czechoslovakia and Czechia. ProfessorJ.Niederle has contributedgreatly to our cooperation. An outstanding theoretician, he has for many years been promoting the development of our collaboration in theoretical physics. As Scientific Sec- retary of the Presidium of the Czech Academy of Sci- ences, he contributedmuch to the solution of strategic issues in our joint activities. Please, accept once more my heartiest congratula- tions on the occasion of Professor Jiří Niederle’s an- niversary. Alexey Sissakian Academician, Director of JINR 112