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Book
1 online resource (x, 251 pages) : illustrations
  • April 9, 1960
  • Walsh
  • Glory days
  • The forties
  • The fifties
  • Twilight
  • Knocked out
  • Brothers.
Lords of the Ring revives the exciting era-now largely forgotten-when college boxing attracted huge crowds and flashy headlines, outdrawing the professional bouts. On the same night in 1940 when Joe Louis defended his heavyweight crown before 11,000 fans in New York's Madison Square Garden, collegiate boxers battled before 15,000 fans in Madison . . . Wisconsin. Under legendary and beloved coach John Walsh, the most successful coach in the history of American collegiate boxing, University of Wisconsin boxers won eight NCAA team championships and thirty-eight individual titles from 1933 to 1960. Badger boxers included heroes like Woody Swancutt, who later helped initiate the Strategic Air Command, and rogues like Sidney Korshak, later the most feared mob attorney in the United States. A young fighter from Louisville named Cassius Clay also boxed in the Wisconsin Field House during this dazzling era. But in April 1960, collegiate boxing was forever changed when Charlie Mohr- Wisconsin's finest and most popular boxer, an Olympic team prospect-slipped into a coma after an NCAA tournament bout in Madison. Suddenly, not just Mohr's life but the entire sport of college boxing was in peril. It was to be the last NCAA boxing tournament ever held. Lords of the Ring tells the whole extraordinary story of boxing at the University of Wisconsin, based on dozens of interviews and extensive examination of newspaper microfilm, boxing records and memorabilia.
(source: Nielsen Book Data)9780299204242 20180521
Book
1 online resource (Pages: 4 ) : digital, PDF file.
HISTRAP is a proposed 2.67 T-m synchrotron-cooler-storage ring having eight 45/degree/, C-design dipole magnets. A prototype dipole has been designed, fabricated, and mapped. The magnet design utilizes curved and angled coil ends to compensate for end effects in the field. Construction of the prototype dipole has been completed by the FNAL magnet factory. The magnetic field has been mapped using a Hall-effect probe afixed to a newly constructed, PC-based, horizontal positioning system. Results of the field mapping are presented. 6 refs., 7 figs., 1 tabs.
Book
1 online resource (Pages: 6 ) : digital, PDF file.
HISTRAP, Heavy Ion Storage Ring for Atomic Physics, is a proposed 2.67-Tm synchrotron/cooler/storage ring optimized for advanced atomic physics research which will be injected with ions from either the HHIRF 25-MV tandem accelerator or a dedicated ECR source and RFQ linac. Over the last two years, hardware prototypes have been developed for difficult and long lead-time components. A vacuum test stand, the rf cavity, and a prototype dipole magnet have been designed, constructed, and tested. 7 refs., 8 figs., 2 tabs.
Book
1 online resource (Pages: 7 ) : digital, PDF file.
HISTRAP is a proposed synchrotron-cooling-storage ring optimized to accelerate, decelerate, and store beams of highly charged very-heavy ions at energies appropriate for advanced atomic physics research. The ring is designed to allow studies of electron-ion, photon-ion, ion-atom, and ion-ion interactions. An electron cooling system will provide ion beams with small angular divergence and energy spread for precision spectroscopic studies and also is necessary to allow the deceleration of heavy ions to low energies. HISTRAP will be injected with ions from either the existing Holifield Heavy Ion Research Facility 25-MV tandem accelerator or from a dedicated ECR source and 250 keV/nucleon RFQ linac. The ring will have a maximum bending power of 2.0 T.m and have a circumference of 46.8 m.
Book
1 online resource (Pages: 41 ) : digital, PDF file.
HISTRAP, Heavy Ion Storage Ring for Atomic Physics, is a proposed 46.8-m-circumference synchrotron-cooling-storage ring optimized to accelerate, decelerate, and store beams of highly charged very-heavy ions at energies appropriate for advanced atomic physics research. The ring is designed to allow studies of electron-ion, photon-ion, ion-atom, and ion-ion interactions. An electron cooling system will provide ion beams with small angular divergence and energy spread for precision spectroscopic studies and also is necessary to allow the deceleration of heavy ions to low energies. HISTRAP will have a maximum bending power of 2.0 Tm and will be injected with ions from either the existing Holifield Heavy Ion Research Facility 25-MV tandem accelerator or from a dedicated ECR source and 250 keV/nucleon RFQ linac.

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