DOCSLIB.ORG

CNRS LABORATORIES - CNRS Research Units Are Spread Throughout France (1,256 Research and Service Units)

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
CNRS LABORATORIES - CNRS Research Units Are Spread Throughout France (1,256 Research and Service Units) 1 PUBLIC RESEARCH PLAYERS Ministry of Research (attached to the Ministry of National and Higher Education and Research) Research Organizations Universities Action funds, translated to a Funding Agency in 2005 (ANR) S & T Organisations CNRS (~ 26.500) CIRAD (~1.850) INRA (~ 8.500) INSERM (~ 5.200) IRD (~ 1.600) IFREMER (~1.400) INRIA (~ 1.000) CEMAGREF (~ 600) CEA (~12.000) etc. Foundations Pasteur Institute, Curie Institute, etc. 2 What is CNRS ? • CNRS has Laboratories  136 in-house laboratories  790 laboratories associated mainly with universities, other French Institutions (INSERM, INRA, INRIA, CEA) and Companies • CNRS funds scientific programs • CNRS covers all the scientific fields from maths to social sciences 3 ORGANIZATIONAL CHART 4 CNRS LABORATORIES - CNRS Research units are spread throughout France (1,256 research and service units) - large body of permanent staff (researchers, engineers, technicians and administrative staff - laboratories are on 4-year contracts, renewable, with bi- annual evaluation - there are 2 types of laboratories : CNRS-only labs (15 %) : fully funded and managed by CNRS CNRS Joint labs (85 %) : partnered with universities, industry or other research organizations 5 CNRS ADMINISTRATIVE REGIONS 6 CNRS STAFF 26.457 permanent staff • Researchers 11.652 • Engineers, Technicians, Administrative staff 14.607 + Non permanent staff payed on governmental subsidies ~ 2.200 (~ 800 associated or foreign scientists ~1.400 granted PhD and Post doc scientists) + Non permanent staff payed on contracts ~ 1.800 7 8 SCIENTIFIC DEPARTMENTS AND INSTITUTES Nuclear and Particle Physics / IN2P3 Mathematics and Physics Information and Communication Science and Technology Engineering Sciences Chemical Sciences Sciences of the Universe / INSU Life Sciences Humanities and Social Sciences 9 Nuclear and Particle Physics Research on the ultimate components of matter and on the early Universe Designing the accelerators of the future Playing an active role in information technology development 10 Mathematics and Physics Applied Mathematics Physics: Carbon nanotubes, cooled atoms, functional materials, physics-biology-medical interfaces, highly correlated fermions Droplet-film transition SW Nanotube between SC Cottrell clouds (ATI) 11 Information and Communication Science and Technology Four research fields: Î Computing and information processing Î Components and systems Î Micro, nano-technologies and systems Î STIC and Human interface 24 Pluridisciplinary programs, 26 Specific actions JemSTIC: young teams, young researcher and mobility 12 Engineering Assembling and transposing knowledge Process automation and management 4 Research themes: ÎTransport: materials, engine, fuel cells… ÎEnergy: renewable, waste, storage… ÎStructural and functional materials, biomechanics… ÎEnvironment, clean processes, pollution… Desalination pilot project Experimental study and numerical simulation of a skull-brain complex subjected to an impact 13 Chemistry Health:Vector for drugs(Cancer,AIDS) Environment: sulfur reduction Materials: nano-tubes fibers New analysis techniques, mass spectro, positron annihilation, … New Molecules Enhancing sensitivity of Materials that “grips” photographic emulsions Sucrose in aqueous media 14 Science of the Universe Astronomy-astrophysics: Universe structure,stars formation, solar system Earth Sciences: Ocean, atmosphere, earth, natural risks, climate, space detection Seismic hazard in Turkey CO2 in ocean and athmosphere Dark matter in the Universe 15 Life Sciences Genomic, bio-computing, functional and structural Structure-function relationship of macromolecules Role of genes in the development and function control of organism Micro-organism physiology Bio-diversity of eco-systems 3D view of the hepatisis C virus Transgenic silkworms (flurescent protein) Algae defense mechanism (Chondrus crispus) 16 Craniofacial malformation Humanities and Social Sciences Inter-disciplinary Res. Intra-disciplinary Res. Main topics Cognitive science History Work and social change Information society linguistics Urban issues and the biology and culture Law crisis of the social link Public policies Asia-Pacific research center (Provence Univ.) Information technology support for linguistics Two negative handprints (Borneo) 17 CNRS AWARDS 11 Nobel Prizes awarded to CNRS researchers Physics : Alfred Kastler (1966), Louis Néel (1970), Pierre-Gilles de Gennes (1991), Georges Charpak (1992) and Claude Cohen-Tannoudji (1997) Chemistry : Jean-Marie Lehn (1987) Biology and medicine : André Lwoff, Jacques Monod and François Jacob (1965), Jean Dausset (1980) Economics : Maurice Allais (1988) 7 Fields medals in mathematics Jean-Pierre Serre, René Thom, Alexandre Grothendieck, Alain Connes, Laurent Schwarz, Pierre-Louis Lions and Jean-Christophe Yoccoz 18 EVALUATION PROCEDURE National Committee for Scientific Research Composition • 41 sub-Commissions (2/3 of the member are elected) • Interdisciplinary Commissions Role • Evaluation (on a 4 year-basis) of ¾ Laboratories ¾ Research Programmes ¾ Researchers • Recruitment of scientists at CNRS 19 R & D BUDGET Financial Law 2005 (billion euros) Governmental Budget 288.8 Civilian Budget 246.4 Civilian R&D Budget 9.3 Research Ministry Budget 6.5 Research Organizations 6.0 Public S&T Organizations 3.8 CNRS Budget 20 2.4 CNRS TOTAL BUDGET 2.4 billion € 1/4 of French civilian research budget Own funds 366 M€ 16 % Government subsidies 1 952 M€ 84 % 21 ORIGIN OF CNRS OWN FUNDS 340.9 M€ (tax excluded) Donations etc. 21.8 M€ (6%) Investment funds 34.1 M€ (10%) Functioning funds Research Contracts 37 M€ (11%) 167.1 M€ (49%) Providing Services 35.8 M€ (11%) Royalties (patents, licenses) 45,0 M€ (13%) 22 INDUSTRIAL RELATIONS (Innovation Law launched in 1999) • 3,280 contracts signed in 2003 • 80 industrial partners among which 370 small and medium sized companies • 150 million euros of revenues generated (EC contracts not included) • 2,657 research applications in effect • 295 exclusive patents applied for in 2003 • 558 active licensing agreements of which 20 % with start-ups • 47.5 million euros royalties • 190 new firms created with CNRS laboratories or CNRS joint laboratories 23 THE CURRENT REFORM… A new Direction of Scientific Strategy Objectives : - scientific orientations better defined - more interdisciplinarity - less administration, more scientific strategy - more interactions between headquarters and regional organisation 24 INTERNATIONAL CNRS ACTIVITIES • More than 20 000 annual publications • = 50% total French publications, 6 % European publications, 2,5% world publications • 45% of the papers are co-signed with foreign scientists • 30% of CNRS papers are co-signed with European partners 25 CNRS OFFICES ABROAD 26 INTERNATIONAL COOPERATION CNRS Budget 2004 (M euros) % Europe 3.06 45 North and South America 1.32 19 Africa and Middle-East 0.84 12 Asia and Pacific 1.54 23 Total (without salaries) 6.8 27 INTERNATIONAL RELATIONS CNRS tools • 85 Bilateral agreements signed with more than 50 countries • ca 200 International Programs for Scientific Cooperation (PICS) • 32 International Associated Laboratories (LIA) • 38 International Research Networks (GDRI) •15 International Joint Units (UMI) 5,000 research interns from abroad in CNRS laboratories Almost one half of the yearly 23 000 CNRS publications are co-published with foreigners 28 Bilateral agreements Agreements for scientific cooperation are signed between CNRS and foreign Research Organizations. It covers the hosting of researchers for duration of one week to one month, within the framework of joint research projects. The selection of applications is based on the excellence and novelty of the project. Projects involving young researchers are given priority. 29 International Programs for Scientific Cooperation - PICS PICS is a 3 year, non-renewable project established on the basis of an ongoing collaborative relationship having already resulted in co-publication. After approval by the relevant CNRS scientific department, researchers must respond jointly to a call for proposals, which is sent out once a year (from February 1st to March 31) PICS is implemented after a positive co-evaluation by the CNRS and the sponsoring foreign research organization. PICS funding covers visits, meetings, and small equipment. 30 International Research Groups GDRI GDRI is a research network devoid of any legal status which connects public and/or private laboratories. GDRIs are set up for a period of four years, renewable twice. GDRI brings together several laboratories from two or more countries to coordinate research on a specific topic. GDRI program funding is used mainly for mobility, seminars and workshops. 31 International Associated Laboratory LIA- virtual lab It brings together at most three laboratories from CNRS and other countries. They contribute human and material resources to a jointly-defined project A director of the LIA is appointed. The project is coordinated by a scientific management committee. The research program is submitted to the steering committee, composed of representatives of the two partner institutions and established scientists from outside the LIA. LIA agreement is for 4 years, renewable once LIA receives funding from the CNRS and the partner institution, for small equipment, visits, etc. 32 International Joint Units UMI- common lab UMI was first created in 2002. UMIs are located either in France or in another country. It brings together in a common laboratory researchers, engineers, and technicians from CNRS and from the other country UMI is headed by a Director, named jointly by CNRS and the foreign partner institution. The Director is responsible for the management of all of the resources made available to the laboratory. UMI is evaluated every 4 years, and renewed following the same rules as for CNRS laboratories in France. 33 International joint laboratories Genomics and life sciences MICA-MultimediaInformation Communication Applications 34.
Load more

Recommended publications
  • Particle Detectors Lecture Notes
    Lecture Notes Heidelberg, Summer Term 2011 The Physics of Particle Detectors Hans-Christian Schultz-Coulon Kirchhoff-Institut für Physik Introduction Historical Developments Historical Development γ-rays First 1896 Detection of α-, β- and γ-rays 1896 β-rays Image of Becquerel's photographic plate which has been An x-ray picture taken by Wilhelm Röntgen of Albert von fogged by exposure to radiation from a uranium salt. Kölliker's hand at a public lecture on 23 January 1896. Historical Development Rutherford's scattering experiment Microscope + Scintillating ZnS screen Schematic view of Rutherford experiment 1911 Rutherford's original experimental setup Historical Development Detection of cosmic rays [Hess 1912; Nobel prize 1936] ! "# Electrometer Cylinder from Wulf [2 cm diameter] Mirror Strings Microscope Natrium ! !""#$%&'()*+,-)./0)1&$23456/)78096$/'9::9098)1912 $%&!'()*+,-.%!/0&1.)%21331&10!,0%))0!%42%!56784210462!1(,!9624,10462,:177%&!(2;! '()*+,-.%2!<=%4*1;%2%)%:0&67%0%&!;1&>!Victor F. Hess before his 1912 balloon flight in Austria during which he discovered cosmic rays. ?40! @4)*%! ;%&! /0%)),-.&1(8%! A! )1,,%2! ,4-.!;4%!BC;%2!;%,!D)%:0&67%0%&,!(7!;4%! EC2F,1-.,%!;%,!/0&1.)%21331&10,!;&%.%2G!(7!%42%!*H&!;4%!A8)%,(2F!FH2,04F%!I6,40462! %42,0%))%2! J(! :K22%2>! L10&4(7! =4&;! M%&=%2;%0G! (7! ;4%! E(*0! 47! 922%&%2! ;%,! 9624,10462,M6)(7%2!M62!B%(-.04F:%40!*&%4!J(!.1)0%2>! $%&!422%&%G!:)%42%&%!<N)42;%&!;4%20!;%&!O8%&3&H*(2F!;%&!9,6)10462!;%,!P%&C0%,>!'4&;!%&! H8%&! ;4%! BC;%2! F%,%2:0G! ,6! M%&&42F%&0! ,4-.!;1,!1:04M%!9624,10462,M6)(7%2!1(*!;%2!
    [Show full text]
  • Nobel Lectures™ 2001-2005
    World Scientific Connecting Great Minds 逾10 0 种 诺贝尔奖得主著作 及 诺贝尔奖相关图书 我们非常荣幸得以出版超过100种诺贝尔奖得主著作 以及诺贝尔奖相关图书。 我们自1980年代开始与诺贝尔奖得主合作出版高品质 畅销书。一些得主担任我们的编辑顾问、丛书编辑, 并于我们期刊发表综述文章与学术论文。 世界科技与帝国理工学院出版社还邀得其中多位作了公 开演讲。 Philip W Anderson Sir Derek H R Barton Aage Niels Bohr Subrahmanyan Chandrasekhar Murray Gell-Mann Georges Charpak Nicolaas Bloembergen Baruch S Blumberg Hans A Bethe Aaron J Ciechanover Claude Steven Chu Cohen-Tannoudji Leon N Cooper Pierre-Gilles de Gennes Niels K Jerne Richard Feynman Kenichi Fukui Lawrence R Klein Herbert Kroemer Vitaly L Ginzburg David Gross H Gobind Khorana Rita Levi-Montalcini Harry M Markowitz Karl Alex Müller Sir Nevill F Mott Ben Roy Mottelson 诺贝尔奖相关图书 THE PERIODIC TABLE AND A MISSED NOBEL PRIZES THAT CHANGED MEDICINE NOBEL PRIZE edited by Gilbert Thompson (Imperial College London) by Ulf Lagerkvist & edited by Erling Norrby (The Royal Swedish Academy of Sciences) This book brings together in one volume fifteen Nobel Prize- winning discoveries that have had the greatest impact upon medical science and the practice of medicine during the 20th “This is a fascinating account of how century and up to the present time. Its overall aim is to groundbreaking scientists think and enlighten, entertain and stimulate. work. This is the insider’s view of the process and demands made on the Contents: The Discovery of Insulin (Robert Tattersall) • The experts of the Nobel Foundation who Discovery of the Cure for Pernicious Anaemia, Vitamin B12 assess the originality and significance (A Victor Hoffbrand) • The Discovery of
    [Show full text]
  • One Year with the Académie Des Sciences 2012
    One Year with the Académie des Sciences 2012 Encouraging the Science Community Promoting Scientific Teaching Transmitting Knowledge Fostering International Collaboration Playing an Expert and Advisory Role The Académie des Sciences: a modernised institution The Académie des Sciences holds an original position among French scientific institutions: placed under the protection of the President of the French Republic, it is self-governed and only supervised by the French National Audit Office (Cour des comptes). Such independence also stems from the process through which members are appointed: they are peer-elected. Gathering the scientific elite of our country, the Académie des Sciences has adapted to the increasing pace of scientific progress by expanding its membership – now at 245 members aside from Foreign Associate and Corresponding Members – and rejuvenating the profile of the Academy – half of its seats are kept for applicants under 55 years old, which means they are still working – thus making sure the Academy is in direct connection with civil society and economic activities. The Académie des Sciences performs its five missions through finely-tuned coordination between its statutory governance bodies, all members of which have been elected, and Committees providing analysis and advice. Plenary Assembly (Closed-Door Committee - Comité Secret) Permanent Members of the Academy, Corresponding and Foreign Associate Members, spread across Divisions and Division 1 Sections Division 2 Sections Sections Mathematics Select Committee Chemistry
    [Show full text]
  • Georges Charpak (1924-2010) Physicist Who Transformed the Measurement of High-Energy Particles
    COMMENT OBITUARY Georges Charpak (1924-2010) Physicist who transformed the measurement of high-energy particles. S hysicist and campaigner, past few decades have used detec- I B OR Georges Charpak has tors developed or greatly improved C / left an enduring mark on by Charpak and his team. A Pscience, technology and education. From the moment Charpak His invention of a type of particle began working on detectors, he detector — the multiwire propor- was interested in the their medi- tional chamber — revolutionized the cal applications. Although a long- BRUCELLE/SYGM A. collection of data from high-energy time proponent of nuclear energy, physics experiments. The device he was horrified by the radiation allowed physicists to detect new doses that children were exposed to particles and so test fundamental during routine medical X-rays. He theories about the nature of matter. helped co-found several companies Modern variants of the detector are that applied his multiwire detectors still used in high-energy particle to medical imaging, to reduce the accelerators. exposure of patients to radioactive Charpak, who died on 29 Sep- tracers. He also worked closely with tember, was born in eastern Poland surgeons and radiologists to bring to a poor Jewish family. When he was seven, gas-filled box containing a large number these techniques to clinical settings. the family moved to Paris, lured by France’s of parallel detector wires, each connected Influenced by his experiences in wartime healthier economy. After France surren- to individual amplifiers. It recorded the Europe, Charpak’s deep concern for social dered to Germany in 1940, Charpak refused electronic pulses resulting from charged issues led him to apply his knowledge to to wear the yellow Star of David, required particles passing through the gas.
    [Show full text]
  • Madiba, a Inforum Model for Cameroon
    Madiba, a Inforum Model for Cameroon The story of the project Paul Salmon Faculté des Sciences économiques Université de Rennes 1 Inforum World Conference 2012 Firenze Introduction • The idea which conducts this presentation, comes from an interview of two French « Nobel Prize » in Physics. • They are Gilles de Gennes and Charpak, respectively Nobel Prize in 1991 and in 1992 The « Nobel Prize » Pierre-Gilles de Gennes Georges Charpak Anecdote • The reporter asked them which Professor has fascinated them ? Is a very famous mathematics professor, a physics one ? • They unanimously answered Frédéric Jolio- Curie (also Nobel Prize in Physics) • The reporter asked them why him? • They answered for his course on missed experiments. Anecdote • The main idea of the course was to explain to the students what to do or not to do to obtain results in an experiment. • You can remark they have not chosen the person for his capacities to find a solution to a theorical problem. The presentation’s target • This presentation will deliver through the Madiba project some good advices and bad examples in the way to manage a project in which an Inforum model is implied. The presentation’s target • I am not so young but not so old. • What I have learned till 1985. Contents • Things to know about Cameroon • Problems and solutions • Important persons for the project • The context • Our conditions • To build the model • Usual work • The target Madiba’s project THINGS TO KNOW ABOUT CAMEROON Things to know about Cameroon (1) • From developping country to an emerging country • All Africa, in one country.
    [Show full text]
  • Georges Charpak: Hardwired for Science
    INTERVIEW Georges Charpak: hardwired for science On 8 March Georges Charpak turns 85. Here he talks to Paola Catapano about his achievements in physics, his current work in education and his expectations for the LHC. Physicist Georges Charpak joined CERN 50 years ago on 1 May 1959. He retired from the organization in 1991 and now lives in Paris, where he studied and worked for the CNRS before coming to CERN. In August 2008 I visited him (with a cameraman and photographer) at his apartment in rue Pierre et Marie Curie. There is perhaps no better address for a physicist who developed detection techniques that have not only allowed a deeper study of the structure of matter but also found important applications in medicine and other fields. This work led to his Nobel Prize in 1992. The photo session was to complete CERN’s Accelerating Nobels exhibition with photographs by Volker Steger, which was one of the features of the LHC inauguration (CERN Courier December 2008 p26). As we entered Charpak’s chaotic but charming office, he made jokes about his Nobel Prize: “Ca devait être une année creuse” (“It must have been a slack year”) for the Nobel Committee. Then he patiently accepted Steger’s request to make a drawing of his dis- covery with coloured pens on a big sheet of white paper, and finally to sit for the photo session. The caption that he added to his drawing of a wire chamber is a good summary of the value that his contribution made to particle physics: “D’un fil isolé à des centaines de milliers de fils independ- ents” (“From an isolated wire to hundreds of thousands of inde- pendent wires”).
    [Show full text]
  • GEORGES CHARPAK ET L'espci Par Jacques Lewiner
    GEORGES C'est à la fin des années 70 que Pierre-Gilles de Gennes me suggère de rencontrer quelqu'un avec qui, me dit-il, je devrais CHARPAK bien m'entendre. ET L'ESPCI Il est physicien au CERN et a fait d’importantes découvertes dans le domaine des détecteurs. Pierre-Gilles de Gennes pense que l’ESPCI serait un endroit par particulièrement favorable pour permettre à Georges Charpak d’explorer des voies nouvelles hors des grands instruments et Jacques que mon laboratoire pourrait largement bénéficier de sa pré- Lewiner sence. Une première réunion est organisée au cours de laquelle Pierre-Gilles de Gennes vante les caractéristiques particulières de l’ESPCI susceptibles d’attirer Georges Charpak : une grande pluridisciplinarité de sujets, des élèves très bien formés et connaissant non seulement la théorie mais aussi sachant tra- vailler de leurs mains, enfin une politique de brevets particu- lièrement originale et attractive pour des esprits créateurs et entreprenants. Tous ces points séduisent Georges Charpak, en particulier le troisième qui lui ouvre des perspectives nouvelles. Avant même de rejoindre notre École, il commence à déposer des brevets, ce qui, compte tenu de son inventivité sans limite, aurait pu facilement le ruiner. 1 En 1980, Georges arrive dans mon laboratoire. Sur la figure de droite, on voit la préparation de son examen préliminaire d’embauche. Il est déclaré apte… Et très vite, son enthousiasme et ses idées à répétition produisent un fort effet attractif sur les chercheurs et étudiants. Sur le plan scientifique, Georges Charpak est curieux de voir s’il serait possible de réaliser des détecteurs permettant de faire l’imagerie bidimensionnelle de distributions de rayonnements ionisants, beaucoup plus économiques que ceux réalisés au CERN.
    [Show full text]
  • The Nobel on First Page Suzanne De Cheveigné, Eliseo Veron
    The Nobel on First Page Suzanne de Cheveigné, Eliseo Veron To cite this version: Suzanne de Cheveigné, Eliseo Veron. The Nobel on First Page: The Nobel Physics Prizes in French Newspapers. Public Understanding of Science, SAGE Publications, 1994, 3, pp.135. halshs-00171760 HAL Id: halshs-00171760 https://halshs.archives-ouvertes.fr/halshs-00171760 Submitted on 13 Sep 2007 HAL is a multi-disciplinary open access L’archive ouverte pluridisciplinaire HAL, est archive for the deposit and dissemination of sci- destinée au dépôt et à la diffusion de documents entific research documents, whether they are pub- scientifiques de niveau recherche, publiés ou non, lished or not. The documents may come from émanant des établissements d’enseignement et de teaching and research institutions in France or recherche français ou étrangers, des laboratoires abroad, or from public or private research centers. publics ou privés. This research on the way French newspapers treated the two Nobel Prizes for physics awarded to Pierre Gilles de Gennes in 1991 then to Georges Charpak in 1992. It allowed us to demonstrate the specificity (and the stability over time) of the relation to science of the different papers, as well as their relation to their readers. The non-published research report in French is available at http://halshs.ccsd.cnrs.fr/ A short article was published in French as: S de Cheveigné et E. Véron, "La science sous la plume des journalistes", La Recherche 263 (1994) 322. The research was published in English as: S de Cheveigné and E. Véron, "The Nobel on First Page : The Nobel Physics Prizes in French Newspapers", Public Understanding of Science 3 (1994) 135 (manuscript reproduced here with written permission) A version with a more complete presentation of the theoretical framework was published as: S de Cheveigné, "The Nobel on First Page : The Nobel Physics Prizes in French Newspapers" in Rhetoric and Epistemology, (Jostein Gripsrud, Ed.) University of Bergen Working Papers, 1997.
    [Show full text]
  • China-Tour2013 Sino- French Cooperation
    Research & Innovate with Europe! Awareness raising and information tour of China October – november 2013 France - China cooperation in R&D&I Main tools managed by the SST Dr Philippe MARTINEAU Deputy Counsellor, S&T department French Embassy in China Outline I. Introduction II. French S&T department – bilateral tools III. Conclusions SCIENCE in France Pionners of sciences… Serge Haroche (2012) and more recently: 2012 Nobel Physics - Serge Haroche 2011 Nobel Medicine - Jules Hofmann 2010 Fields Maths - Cédric Villani & Ngô Bảo Châu 2009 Abel Maths - Michail Gromov 2008 Nobel Medicine - Françoise Barré-Sinoussi & Luc Montagnier 2008 Abel Maths - Jacques Tits 2007 Nobel Physics - Albert Fert 2006 Fields Maths - Wendelin Werner 2005 Nobel Chemistry - Yves Chauvin 2003 Abel Maths - Jean-Michel Serres 2002 Fields Maths - Laurent Laforgue 1997 Nobel Physics - Claude Cohen-Tanoudji 1994 Fields Maths - Pierre-Louis Lions & Jean-Christophe Yoccoz 1992 Nobel Physics - Georges Charpak 1991 Nobel Physics - Pierre-Gilles de Gennes … Marie Curie (1903 & 1911) 11 Fields medals or 3 Abel prize = « Nobel in maths …& TECHNOLOGY in France Leadership in several technologies High-speed trains (Alstom), Aeronautics (Airbus, Eurocopter *, Dassault, Safran), rockets (Arianespace *) & satellites (Astrium *, Thales-Alenia *), nuclear (Areva) & renewables energies , pharmaceutics (Sanofi & Pasteur), agronomy (Limagrain), etc. * also with European partners Research actors National « research bodies » (25) CNRS all domains (25 500 permanent staff) CEA atomic & alternative
    [Show full text]
  • World Year of Physics Opens with Paris Conference by Ernie Tretkoff the World Year of Physics Was Jose Luis Moran-Lopez, Director Developing Nations
    NEWS February 2005 Volume 14, No. 2 A Publication of The American Physical Society http://www.aps.org/apsnews World Year of Physics Opens with Paris Conference By Ernie Tretkoff The World Year of Physics was Jose Luis Moran-Lopez, director developing nations. In one session, officially launched at the conference of the ISTR San Luis Potosi in Mexico, Katepalli Sreenivasan of the Inter- “Physics for Tomorrow,” which took described a project called “Science national Center for Theoretical place in Paris at UNESCO headquar- for everyone,” a series of books writ- Physics in Trieste, Italy, talked about ters January 13-15. Speakers and ten by active Mexican scientists physics and development. He participants addressed issues such aimed at the high school and college pointed out some of the vast dif- as the public perception of physics level. There are also contests that in- ferences between the developed and how physics can help solve vite students to read one of the world and the developing nations, social and economic problems. books and do a project or report including the availability of About 1000 participants, includ- based on their reading, he said. internet access. Without access to ing approximately 500 students from Also during the round table the latest information, it is difficult over 70 countries, attended the con- discussion, Pierre Lena, vice presi- to practice science, he said. “We ference. Eight Nobel laureates spoke dent of the Association Bernard live in a connected world, but yet on a variety of topics ranging from Gregory, said that many students See WYP PARIS on page 10 biophysics to nanoscience to physics believe that science is out of reach education in lectures aimed at high- for them.
    [Show full text]
  • Gaseous Detectors from (Very) Basic Ideas to Rather Complex Detector Systems Maxim Titov, CEA Saclay, France
    The Physics of Modern Particle Detectors: Gaseous Detectors From (very) basic ideas to rather complex detector systems Maxim Titov, CEA Saclay, France Artist's View of a Bubble chamber by a CERN physicist IEEE NPSS Workshop on Applications of Radiation Instrumentation, Dakar, Senegal, December 3-5, 2020 To do a HEP experiment, one needs: A theory: and a cafeteria Mary Gaillard Murray Gell-Mann and a tunnel for the accelerator and magnets and stuff Clear and easy understandable drawings Easy access to the experiment Physicists to operate detector/analyze data and a Nobel prize We will just concentrate on particle detectors – “gaseous detectors” The History of Instrumentation is VERY Entertaining A look at the history of instrumentation in particle physics complementary view on the history of particle physics, which is traditionally told from a theoretical point of view The importance and recognition of inventions in the field of instrumentation is proven by the fact that several Nobel Prices in physics were awarded mainly or exclusively for the development of detection technologies Nobel Prizes in instrumentation (“tracking concepts”): 1927: C.T.R. Wilson, Cloud Chamber 1960: Donald Glaser, Bubble Chamber 1992: Georges Charpak, Multi-Wire Proportional Chamber ATLAS and CMS Detectors at CERN: Two Giants ATLAS CMS Building of 5 floor 5 The CMS Detector: Concept to Data Taking – Took 18 Years 3000 scientists from 40 countries Scintillating CMS Letter of Intent (Oct. 1992) Crystals Silicon Tracker Brass plastic Gaseous scintillator6
    [Show full text]
  • Albert Einstein
    Albert Einstein Albert Einstein in 1904, when he was working at the Swiss Patent Office at Bern. On 14 March 1879, Albert Einstein The mathematics of the theory with was born at Ulm in Germany. The its interlocked space and time co­ centenary of his birth is being cele­ ordinates, is the bedrock of theory brated throughout the world and it is and of experimental interpretation. appropriate in a journal of high Yet, not many of these conse­ energy physics, a field of research quences could have been foreseen where many of his insights are now by Einstein in 1 905. the bread and butter of daily work, to It could be said that other scien­ pay tribute to this towering figure of tists had been on the brink of evolv­ modern physics. ing the 'special theory of relativity' In a single year, 1905, Albert but none were near Einstein's still Einstein made several dramatic con­ more revolutionary leap in pure tributions to physics. He deduced thought ten years later. He emerged the true nature of Brownian motion with the 'general theory of relativity' (doing much to underline the mole­ bringing gravitation also within the cular and atomic nature of matter), grasp of the theory. It gave the rules he demonstrated the particle nature for the workings of the Universe on a of light in a way which was acces­ cosmological scale, superseding the sible to experimental investigation classical work of Isaac Newton (the work for which he received the which had stood for the preceding Nobel prize) and, most dramatically two centuries.
    [Show full text]