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Organisation for Economic Co-operation and Development Global Science Forum

Organisation for Economic Co-operation and Development Global Science Forum. Large-Scale International Scientific Cooperation: A View from OECD A personal unofficial view IUPAP Commission Chairs Mtg, October 13, 2006 Presentation by Stefan Michalowski, OECD.

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Organisation for Economic Co-operation and Development Global Science Forum

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  1. Organisation for Economic Co-operation and DevelopmentGlobal Science Forum Large-Scale International Scientific Cooperation:A View from OECD A personal unofficial view IUPAP Commission Chairs Mtg, October 13, 2006 Presentation by Stefan Michalowski, OECD

  2. Through the Global Science Forum, senior government officials develop findings and action recommendations on specific science policy issues. 1995 – 2006 Topics: • Neutron Sources • High-Energy Neutrinos • Radio Astronomy • Proton Accelerators • Nuclear Physics I • Structural Genomics • Condensed Matter Facilities • High-Intensity Lasers • Astronomy and Astrophysics • High-Energy Physics • Grid Computing • Science indicators and Models • Science Education • Science for a Safer Society • Bioinformatics • Neuroinformatics • Administrative Practices • Energy Research • Earthquake Science • Nuclear Physics II • Research Misconduct • Scientific Collections

  3. Global Science Forum activities are proposed by member delegations (governments). If approved, they are organised/facilitated by a small secretariat of international civil servants. All Global Science Forum activities result in a publicly-available policy-level report containing findings and action recommendations for governments, inter-governmental organisations, or the international scientific community. www.oecd.org/sti/gsf

  4. Labs & Institutes InternationalOrganizations Funding Agencies Central Science Administrations Advisory Groups & Experts InternationalScientific Orgs. GSF Stakeholders

  5. Lessons learned: Undertaking an activity • Scientific opinion should be mature. Scientists should acknowledge need for some “top down” guidance or help • Interesting science is not enough. Must have a specific problem/challenge/opportunity • Need interest in 3 regions, and at least some propects for success (ideally, a Ministerial-level endorsement at the end) • Boundaries must be correctly chosen, especially given increasing links between fields • Activity must be visible/transparent/inclusive, especially with regard to the scientific community

  6. In most GSF activities, scientific organisations have been invited to participate as equal partners • UNESCO • Euroscience • ICSU • ESF • IAU • IUGG For example, Working Group on Nuclear Physicshas 13 countries, plus: • IUPAP/ICNP • NuPECC • CERN • JINR • EURISOL

  7. Lessons learned: Externalities Globalisation Is Happening • Cold War is over. There are winners and losers, new opportunities and challenges. • Ongoing revolution in computation, communications, travel, transportation • Expertise/resources/issues/data are globally distributed. Emerging nations investing in S&T. • European integration is moving forward.How to reconcile global versus intra-regional cooperation and coordination?

  8. Lessons learned: Externalities, cont. Greater Social Relevance Expected • Economic competitiveness (public, private) can interfere with scientific cooperation • Global-scale issues count (health, environment, energy,…) • National security issues can take precedence • Public attitudes to science are evolving (e.g., young people losing interest, mistakes are more visible) • Lack of reliable indicators and analytical models for assessing societal impact of S&T investments

  9. University graduates in physical sciences in selected countries index 100: 1994 140,0 120,0 100,0 80,0 60,0 40,0 1994 1995 1996 1997 1998 1999 2000 2001 2002 2003 France Germany Korea Netherlands Norway United-States

  10. Average annual growth of S&T graduates: 1995-2003 Life sciences Physical sciences Mathematics and statistics Computing Engineering % 30.0 25.0 20.0 15.0 10.0 5.0 0.0 Korea Turkey France Finland Norway Sweden Portugal Australia Germany Denmark Belgium Fl. Belgium Fr. Netherlands United States United Kingdom -5.0 -10.0 -15.0

  11. Lessons learned: Externalities, cont. Greater Social Relevance Expected • Economic competitiveness (public, private) can interfere with scientific cooperation • Global-scale issues count (health, environment, energy,…) • National security issues can take precedence • Public attitudes to science are evolving (e.g., young people losing interest) • Lack of reliable indicators and analytical models for assessing societal impact of S&T investments

  12. Lessons learned: Changes in science itself Larger Scale of Infrastructures Imposed by Science • Some fields are entering the global-scale megascience era for the first time • The culture of science is changing • Large costs suppress duplication, competition • Smaller number of large facilities aggravates laboratory politics • Supply/demand issues are rarely addressed

  13. Lessons learned:Changes in science itself, cont. Stronger Links Between Scientific Fields • A challenge for traditional academic institutions, funding agencies, scientific organisations. • A challenge for planning, prioritisation, funding, oversight mechanisms as well. Increasing Role of Large User Facilities • National/regional/global balance issues • Access policies become more visible • Need for investments, R&D for instrumentation

  14. Lessons learned:About international cooperation itself Long-range Planning and Prioritising • National/regional cycles are not synchronised,not sufficiently international • The spirit of collaboration and sharing is under-developed • Need venues where scientists/officials can interact (e.g., OECD GSF) • Allowing for serendipity when planning • The international scientific community does not have the inclination or mechanisms for long-range planning, prioritisation

  15. Lessons learned:About international cooperation itself Siting Considerations • Try to keep the politics out; works best when science is the driver, or when choice is obvious • Recognise/acknowledge political dimension • The “fair distribution” approach will probably never work • Take advantage of existing infrastructures • Be sensitive to local concerns • Anticipate decommissioning costs

  16. Lessons learned:About international cooperation itself Organising Large Collaborations • Understanding the options for legal/organisational/managerial structures • Speaking the same language about budgets, project stages, approvals, etc. • Being clear about access policies • Many collaboration issues – big and small - will be decided by negotiating agencies • The intergovernmental negotiations take lots of time

  17. Lessons learned: Pitfalls • Resolve scientific disputes elsewhere first. • Try to direct action recommendations to the right authority. Avoid “Someone should do something” • Don’t tackle an issue that is too easy, too hard or politically intractable. • Try to arrange some kind of follow-up. Formulate Ministerial recommendation of possible.

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