Fermilab Documents List

Fermilab 1967 list

Last modified at 07:25:30 updated on 11/23/09.

    1967

  1. Billinge, R. main ring aperture requirements;
  2. Billinge, R. closed orbit distortion due to misalignment;
  3. Blewett, M.H. some comments about beam transport magnets;
  4. Blewett, M.H. notes on building costs for argonne 12-ft bubble chamber and second proton area;
  5. Blewett, M.H. estimate of temporary structures required for 200-gev accelerator's experimental areas;
  6. Cole, F.T. estimates of conversion from 200-bev to 400-bev;
  7. Courant, E.D. a separated function lattice for the nal booster;
  8. Courant, E.D. longitudinal space charge forces at transition: scaling relations;
  9. Courant, E.D. bypass storage ring option for nal;
  10. DeWire, J. shielding requirements for the 200-gev accelerator;
  11. Eagling, D. rough estimating figures for experimental areas;
  12. Garren, A. main accelerator lattice;
  13. Goldwasser, E.L. facilities and plans for the experimental program at the 200-gev accelerator;
  14. Gram, R. advantages of a set of second harmonic rf cavities;
  15. Hartwig, E.C. power requirements of the 200-gev facility;
  16. Jovanovic, D. the sensible secondary beam elements for the 200-gev accelerator;
  17. Kerns, Q.A. main ring rf notes;
  18. Koester, L. fluxes of particles in secondary beams;
  19. Krisch, A.D. note on area for p p experiments with internal target;
  20. Krisch, A.D. estimate of particle production in 200-gev proton proton collisions;
  21. Krisch, A.D. thin target area;
  22. Krisch, A.D. possible experiments on the 200-gev accelerator;
  23. Krisch, A.D. note on front porch;
  24. Lambertson, G.R. model of experimental program;
  25. Littauer, R. information transmission by time programmed multiplexing;
  26. Livingston, M. Stanley shape of gradient magnets for 200-gev accelerator;
  27. Livingston, M. Stanley the 200 billion volt accelerator;
  28. Livingston, M.S. control of radiation;
  29. Longo, M.J. note on magnets for use in high-energy beams at the proposed 200-gev accelerator;
  30. Malamud, E. main ring pumping system;
  31. Maschke, A. notes on ripple requirements for slow extraction and some parameters relative to correcting the spill;
  32. Maschke, A. some general conditions for the long transport system of the external beam;
  33. Maschke, A. casting shadows on septa;
  34. Maschke, A.W. note on the effective width of septa and theoretical maximum extraction efficiency;
  35. Maschke, A.W. some general criteria for the design of an optimum extraction channel;
  36. Meyer, D. criteria and parameters for epb transport;
  37. Meyer, D. secondary beam transport equipment;
  38. Meyer, D.I. low intensity epb experimental areas;
  39. Morton, P. an unsuccessful attempt to reduce the phase oscillation frequency by a phase shift between accelerating cavities;
  40. Read, Anthony Lincoln notes on power distribution in the experimental areas: a summary;
  41. Regenstreif, E. is it possible to achieve a matrix of +1 by means of a quadrupole quadruplet?;
  42. Regenstreif, E. angular and phase acceptance of a quadrupole beam transport channel;
  43. Roberts, A. experimental area design with minimal modular shielding;
  44. Roberts, A. note on the choice of shielding material in experimental areas;
  45. Romano, V.J. search for low cost shielding;
  46. Rubinstein, R. target station b;
  47. Salsig, W.W. mark-iii internal target area guess;
  48. Salsig, W.W. observations on various features of nal experimental area proposals;
  49. Salsig, W.W. significant features of power and cooling system considerations for experimental area secondary beams;
  50. Salsig, W.W. cooling systems: overall comparisons;
  51. Salsig, W.W., Jr. preliminary approximation: cost of internal target area, epb stub, and experimental hall;
  52. Sanford, J.R. some thoughts on experimental areas;
  53. Serber, R. cross sections at large momentum transfer;
  54. Snowdon, S.C. slow injection into 1000-meter radius accelerator;
  55. Snowdon, S.C. fast slow booster injector system;
  56. Teng, L. a proposed small radius, separate function booster;
  57. Teng, L.C. nal separate function 10-gev booster;
  58. Teng, L.C. auxiliary magnets and windings in the main accelerator;
  59. Teng, L.C. multiturn injection into the main accelerator;
  60. Teng, L.C. error and tolerance analysis for the main accelerator;
  61. Teng, L.C. regular cell structure;
  62. Thomas, R.H. 400-gev accelerator project radiation problems;
  63. Thomas, R.H. 200-gev - 400-gev accelerator project radiation problems;
  64. Van Steenbergen, A. preliminary note on a separated function booster;
  65. van steenbergen, A. some notes related to: a. direct injection into the main ring b. vertical versus horizontal injection c. main ring injection;
  66. Walker, G. reduction of beamline power;
  67. Walker, T.G. target station c: preliminary layout of beams;
  68. Walker, T.G. target station a: preliminary layout of beams;
  69. Walker, T.G. experimental area c;
  70. Wattenberg, A. basis for reducing the lateral shielding in the b & c target areas;
  71. Wenzel, W.A. proposal for series targeting: thin parasitic intermediate targets;
  72. Wilson, Robert Rathbun some aspects of the 200-gev accelerator;
  73. Yamada, R. a method of colliding beam;
  74. Yuan, L.C.L. scientific justification;