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Swapan Chattopadhyay

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Name
  
Swapan Chattopadhyay

Role
  
Physicist

Fields
  
Physics


Swapan Chattopadhyay casajlaborggraphicsmembersswapanjpg

Born
  
December 26, 1951 (age 72) Calcutta, West Bengal, India (
1951-12-26
)

Residence
  
Cheshire, UK and California, USA

Nationality
  
USA (Naturalized in the USA in 1995 as Swapan Chaterji)

Institutions
  
Thomas Jefferson National Accelerator Facility (2001-2007) University of California at Berkeley (1974-1982, 1984-2001) Lawrence Berkeley National Laboratory (1976-1982, 1984-2001) CERN (1982-1984)

Alma mater
  
University of California (1974-1982) University of Oregon (1972-1974) Indian Institute of Technology (1970-1972) St. Xaviers College (1967-1970)

Known for
  
Particle accelerator science and technology

Influences
  
Early childhood in Darjeeling Pramatha Nath Patra (High school physics mentor) Owen Chamberlain (Academin post-graduate mentor)

Education
  
Indian Institutes of Technology, University of Oregon, St. Xavier's College-Autonomous, Mumbai

Breaking New Ground


Swapan Chattopadhyay (born December 26, 1951) is a particle accelerator physicist noted for his pioneering contributions of innovative concepts, techniques and developments in high energy particle colliders, coherent and incoherent light sources, ultrafast sciences in the femto- and atto- second regimes, superconducting linear accelerators and various applications of interaction of particle and light beams. He has directly contributed to the development of many accelerators around the world, e.g. the Super Proton-Antiproton Synchrotron at CERN, the Advanced Light Source at Berkeley, the asymmetric-energy electron-positron collider PEP-II at Stanford, the Continuous Electron Beam Accelerator facility (CEBAF) at Jefferson Lab and the Free-Electron Lasers at Jefferson and Daresbury Laboratories.

Contents

Currently, Chattopadhyay holds the Presidential Chair of Research, Scholarship and Artistry at Northern Illinois University (NIU) where he is Professor of Physics and Director of Accelerator Research. Concurrently he holds a joint appointment with Fermi National Accelerator Laboratory (Fermilab) where he is a distinguished scientist, member of the director’s senior leadership team and director of the Cooperative Research and Development Agreement between Fermilab and NIU. He was formerly the Sir John Cockcroft Chair of Physics jointly at the Universities of Liverpool, Manchester and Lancaster — the First Chair of accelerator physics in UK, named after the British Nobel Laureate credited with creating the field. In this role he was the Inaugural Director of the Cockcroft Institute (UK), having been appointed in April 2007. Prior to this he served as Associate Director of Thomas Jefferson National Accelerator Facility (2001–2007); Staff/ Senior Scientist and Founding Director of the Centre for Beam Physics at Lawrence Berkeley National Laboratory (1984–2001); and Scientific Attaché at CERN (1982- 1984). Having spent his early childhood in Calcutta and Darjeeling in India, he completed his undergraduate studies as a National Scholar and National Science Talent Scholar before receiving his Ph.D. in Physics from University of California at Berkeley in 1982. He had held Visiting Professor appointments at University of California at Berkeley, Harvard University, University of Illinois at Urbana Champagne and University of Virginia at Charlottesville at various times. He is a Fellow of the American Physical Society, American Association for the Advancement of Science, Institute of Physics (UK) and Royal Society of Arts, Manufactures and Commerce (UK) and a member of many international panels and committees, including the “International Committee for Future Accelerators” and the DESY Science Council. He had served as the Vice-Chair, Chair-elect, Chair and Past-Chair of the American Physical Society’s Division of Physics of Beams (2007–2011). He has mentored many scientists and engineers across the globe including Asia, North America and Europe and has delivered endowed lectures throughout the world e.g. Saha Memorial Lecture, Homi Bhabha Lecture, Raja Ramanna Memorial Lecture, and Cavendish Lecture among many.

Early childhood

Swapan Chattopadhyay was born in Calcutta, India and spent his impressionable early childhood years in the Himalayan hill town of Darjeeling. His father, educated as a chemist but trained in telecommunications via his chosen profession, was posted, from the mid 1950s till the early 1960s, in Darjeeling as the “officer-in-charge” of communications in the mountain districts of Darjeeling, Sikkim, parts of Bhutan, Nepal and Tibet (now China) on behalf of the Post, Telegraph and Telephone (PT&T) department of India. There growing up as a young boy, along with developing an appreciation for the region’s famously exotic tea gardens and five-mile high mountain peaks, he was fascinated with spotting the Sputnik in the sky and was also one of a half dozen fortunate children who were offered hand-held mountaineering lessons by Sir Edmund Hillary and Tenzing Norgay, upon inauguration of the pioneering Himalayan Mountaineering Institute by the governments of India and New Zealand in 1957. This started his lifelong fascination with science on the one hand and climbing mountains and trekking on the other, in addition to an addiction for tea. At one point in his formative years, he had seriously considered the profession of mountain climbing and much later in life, has been driven to explore the remote regions of western Tibet, the sources of the rivers Indus and Brahmaputra, the sacred mountain Kailas and lake Manasarovar. The Indo-China conflict over the disputed territory of Tibet and subsequent flight of Dalai Lama from Tibet into India brought serious conflicts in the mountain region, putting considerable stress in the civilian population. He relocated with family to the metropolitan mega-city of Calcutta in the early 1960s, where he received high school and university education. He was awarded a high school diploma in 1967 as a National Scholar, graduating from Ballygunge Government High School and was selected a National Science Talent Scholar in a nationwide competition. The high school had also previously graduated the internationally acclaimed Bengali film director Satyajit Ray, who along with another contemporary Bengali radical film director Ritwik Ghatak, had considerable influence on his young mind. It was in this high school, that he was the beneficiary of the gifted mentorship of the school’s legendary physics teacher, Pramatha Nath Patra.

Higher education and early career

Chattopadhyay completed his B.Sc. degree from Calcutta University in 1970, with Honors in Physics, graduating from St. Xavier’s College, a well known institution run by the early Jesuit clergy in India, which also boasts of having graduated the famous Indian scientist Prof. Jagadish Chandra Bose and Indian steel tycoon Laxmi Mittal. Caught in the turmoil of the politically vibrant and active university community in the city of Calcutta in the state of West Bengal in the late 1960s and early 1970s, he circumvented a delayed prospect of admission into the university’s post-graduate program by joining the Indian Institute of Technology at Kharagpur, eighty miles south-west of Calcutta, for his post-graduate studies, completing his M.Sc. degree with specialization in Particle Physics in 1972. Hoping to combine his passion for physics with the desire to explore nature, and upon direct invitation from Prof. Michael Moravscik as Chair of the Physics Interview Committee of the American Physical Society, he then joined in 1972 the Physics department of the University of Oregon at Eugene in the Pacific Northwest region of USA, known for its rugged natural beauty. However, over time, the draw towards the larger, diverse and vibrant campus of the University of California at Berkeley got stronger and with direct support and recommendation from Prof. Rudy Hwa and Prof. Berndt Crasemann while working on research projects with them in the summers of 1973 and 1974, he joined the University of California at Berkeley in 1974, as a Ph.D. student in the Department of Physics. After flirting for two years (1974-1976) with the inimitable Berkeley brand of theoretical particle physics, then known as the “S-matrix” and “Bootstrap” theories of “strong interactions”, under tutelage of Prof. Geoffrey Chew, Chattopadhyay was attracted away by the eclectic and pragmatic charm of accelerator physics dealing with charged particle and light beams under mentorship of some of the most prominent accelerator pioneers in the original accelerator laboratory created by Ernest Orlando Lawrence at Berkeley, such as: Edward J. Lofgren, Andrew Sessler, Denis Keefe, L. Jackson Laslett and Glen Lambertson, to name a few. In 1978, he was also heavily influenced by the visit of Simon van der Meer and Carlo Rubbia to the laboratory, speaking on the possibilities of stochastic phase space cooling of antiproton beams and the exciting possibilities with proton-antiproton collisions. He was also simultaneously being encouraged by Prof. Owen Chamberlain, discoverer of the ‘antiproton’ and a Berkeley Nobel laureate, to engage in antiproton beam research. He subsequently completed his PhD dissertation on the timely and critical topic of stochastic cooling of bunched beams of antiproton from the University of California (Berkeley) Physics department in 1982 and continued onto CERN as an “attaché scientifique” in the Super Proton Antiproton Synchrotron working with Daniel Boussard, Simon van der Meer and Carlo Rubbia, contributing to the ongoing program of stochastic cooling of antiproton beams, which led to the discovery of the W and Z vector bosons at CERN, and to the early ideas of stochastic cooling of “bunched” beams, which today are being applied successfully to phase space cooling of heavy ions at the Relativistic Heavy Ion Collider at Brookhaven National Laboratory, leading to exciting new investigations of the ‘quark-gluon’ plasma in gold-on-gold collisions.

Career

Chattopadhyay returned to Lawrence Berkeley National Laboratory in 1984, where he led and defined the accelerator physics of the Advanced Light Source (ALS) and contributed to the conceptual design of the Superconducting Super Collider (SSC), pioneered the accelerator physics which underpinned the Berkeley-Stanford asymmetric B-factory (PEP-II) for CP-violation studies, and initiated the Berkeley FEL/Femtosecond X-ray Source and Laser-Plasma Acceleration development. He was a Senior Scientist, a Guest Professor, and the Founder/Director of the Center for Beam Physics at Berkeley, until his move to Thomas Jefferson National Accelerator Facility in 2001 as the Associate Laboratory Director for Accelerators, after 25 years at the University of California and Lawrence Berkeley National Lab. At Thomas Jefferson National Accelerator Facility, he made critical advancements in microwave superconducting linear accelerators leading the way to current and future grand instruments of science such as the high precision CEBAF and its 12 GeV upgrade for precision research in hadronic physics, Spallation Neutron Source at Oak Ridge National Laboratory, USA to advance neutron sciences and novel materials research, and the current superconducting version of the International Linear Collider, to name a few. His research at the Cockcroft Institute in UK included development of sources of “ultra-cold” relativistic free electron beams to advance coherent electron diffraction techniques; production of novel coherent and ultra-short pulses of photons (e.g. x-ray FELs); novel acceleration methods; investigation of photonic crystals and metamaterial structures for charged particle acceleration; novel high energy colliders; cavity search for “dark matter” and laboratory investigation of “dark energy” via atom interferometer techniques. Chattopadhyay is currently working for Fermilab and Northern Illinois University (NIU) acting as a distinctive professor and director of accelerator research. Having contributed to the conception, design, construction, commissioning and operation of numerous accelerators for particle and nuclear physics, photon and neutron sciences around the world, with significant research accomplishments in advanced particle and photon beam physics, and mentoring scientists around the world, in the developing nations in particular, in accelerator developments as a unifying global force among nations, Prof. Chattopadhyay is a frequently invited speaker and advisor at professional societies and government research agencies, serving on numerous editorial, advisory and review committees throughout the world.

Stochastic Phase-Space Cooling of ‘Radio-Frequency Bunched’ Beams

  • "On Stochastic Cooling of Bunches in the Colliding Beam Mode in High Energy Storage Rings," S. Chattopadhyay, IEEE Trans. on Nucl. Sci., 1983, Vol. NS-30, No. 4, p. 2334.
  • "Theory of Bunched Beam Stochastic Cooling," S. Chattopadhyay, IEEE Trans. on Nucl. Sci., 1983, Vol. NS-30, No. 4, p. 2649.
  • "Feasibility Study of Stochastic Cooling of Bunches in the SPS," D. Boussard, S. Chattopadhyay, G. Dome and T. Linnecar, CERN 84-15, 1984, p. 197. Proc. CERN Accelerator School on Antiprotons for Colliding Beam Facilities (1984).

    • Synchrotron radiation sources and free electron lasers

  • "Design Concepts of a Storage Ring for a High Power XUV Free Electron Laser", M. Cornacchia, J. Bisognano, S. Chattopadhyay, A. Garren, K. Halbach, A. Jackson, K. J. Kim, H. Lancaster, J. Peterson, M. S. Zisman, C. Pellegrini and M. S. Zisman, Nucl. Instrum. Meth. Phys. Res. A 250 (1986), pp. 57–63.
  • "Beam Instabilities", M. Furman, J. Byrd and S. Chattopadhyay, Chapter 12, Synchrotron Radiation Sources A Primer, World Scientific, (Herman Winick, Ed.), Series on Synchrotron radiation Techniques and Applications – Vol 1.
  • "An infrared free electron laser system for the proposed chemical dynamics research laboratory at LBL based on a 500 MHz superconducting linac", K.-J. Kim, R. Byrns, S. Chattopadhyay, R. Donahue, J. Edighoffer, R. Gough, E. Hoyer, W. Leemans, J. Staples, B. Taylor and M. Xie, Nucl. Instrum. Meth. Phys. Res. A 341 (1994), pp. 289–284.

    • Asymmetric B-Factory

  • "Physics and Design Issues of Asymmetric Storage Ring Colliders as B-Factories," S.

    • Femtosecond X-Rays

  • “Generation of Femtosecond X-rays by 90˚ Thomson Scattering,” K.-J. Kim, S. Chattopadhyay and C.V. Shank, Nucl. Instrum. Meth. Phys. Res. A 341 (1994), pp. 351–354.
  • “Femtosecond X-ray Pulses at 0.4 Å Generated by 90˚ Thomson Scattering: A Tool for Probing the Structural Dynamics of Materials,” R. W. Schoenlein, W. P. Leemans, A. H. Chin, P. Volfbeyn, T. E. Glover, P. Balling, M. Zolotorev, K. –J. Kim, S. Chattopadhyay, and C. V. Shank, Science, 274, 11 Oct. 1996, p. 236.
  • “X-Ray Based Subpicosecond Electron Bunch Characterization Using 90˚ Thomson Scattering,” W. P. Leemans, R. W. Schoenlein, P. Volfbeyn, A. H. Chin, T. E. Glover, P. Balling, M. Zolotorev, K. J. Kim, S. Chattopadhyay, and C. V. Shank, Phys. Rev. Lett., 77, No.20, p. 4182 (11 Nov.,1996).
  • “Interaction of Relativistic Electrons with Ultrashort Laser Pulses: Generation of Femtosecond X-rays and Microprobing of Electron Beams”, W.P. Leemans, R.W.Schoenlein, P.Volfbeyn, A.H.Chin, T.E.Glover, P.Balling, M.Zolotorev, K.-J,Kim, S. Chattopadhyay and C.V.Shank, IEEE Journal of Quantum Electronics, Vol. 33, No. 11, November 1997, p. 1925.
  • “Alight a Beam and Beaming Light: A theme with Variations,” S. Chattopadhyay, Physics of Plasmas, Vol. 5, Number 5, p. 2081 (1998).
  • “Generation of Femtosecond Pulses of Synchrotron Radiation”, R. W. Schoenlein, S. Chattopadhyay, H.H.W.Chong, T.E.Glover, P.A.Heimann, C.V.Shank, A.A.Zholents, M.S.Zolotorev, Science, 287, March 24, 2000, p. 2237.
  • “Generation of femtosecond X-ray pulses via laser-electron beam interaction”, R. Schoenlein, S. Chattopadhyay, H. H. W. Chong, T. E. Glover, P.A. Heimann, W.P.Leemans, C.V. Shank, A. A. Zholents and M. S. Zolotorev, Appl. Phys. B 71, 1-10, 2000.
  • “Femtosecond X-ray generation through relativistic electron beam-laser interaction”, Wim Leemans, Swapan Chattopadhyay, Eric Esarey, Alexander Zholents, Max Zolotorev, Alan Chin, Robert Schoenlein, Charles V. Shank, Compte. Rendu. Acad. Sci. Paris, t.1, Serie IV, p. 279-296, 2000.
  • “Inverse Compton backscattering source driven by the multi-10 TW laser installed at Daresbury”, G. Priebe, D. Laundy, M. A. MacDonald, G. P. Diakun, S. P. Jamison, L. B. Jones, D. J. Holder, S. L. Smith, P. J. Phillips, B. D. Fell, B. Sheehy, N. Naumova, I. V. Sokolov, S. Ter-Avetisyan, K. Spohr, G. A. Krafft, J. B. Rosenzweig, U. Schramm, F. Gruner, G. J. Hirst, J. Collier, S. Chattopadhyay and E. Seddon, Lasers and Particle Beams (2008), 26, 649-660, Cambridge University Press.

    • Microwave Superconductivity and Precision Beams

  • “Strange-Quark Contributions to Parity-Violating Asymmetries in the Forward G0 Electron-Proton Scattering Experiment”, Collaboration G0, D. Armstrong et al., Phys. Rev. Lett. 95, 092001 (2005).
  • “Transverse Beam Spin Asymmetries in Forward-Angle Elastic Electron-Proton Scattering”, Collaboration G0, D. S. Armstrong et al., Phys. Rev. Lett., 99, 092301 (2007).
  • “Hurricane Isabel gives accelerators a severe test”, CERN Courier, January/February 2004, 44(1), pages 37–39.

    • Large Hadron Collider

  • “Accelerator Physics Challenges of the Large Hadron Collider”, Indian National Academy of Sciences, Springer Verlag, 2009.

    • References

    Swapan Chattopadhyay Wikipedia
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