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Role of shielding cuts in high-energy diffraction scattering

Роль зкранируюших раэреэов при дифракционном рассеянии при высоких знергиях

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Il Nuovo Cimento A (1965-1970)

Summary

Regularities of high-energy diffraction scattering emerging from the experimental investigation of pp, πp and Kp scatterings are discussed in the context of a model with a shielded pomeron. In this model, exchange degeneracy of secondary trajectories is valid over a wide energy range and the leading singularities in thej-plane are factorizable. The pomeron singularity is essentially aSU 3 singlet.SU 3 breaking at medium-high energies is attributed to a nearby singularity, namely the shielding cut. An important consequence of the present model is the prediction that the structure observed in the pp angular distribution at low |t| values should be absent in the diffraction peak in K+p scattering. Finally, on the basis of the singularity structure in the model, it is argued that the energy dependence of the diffraction slopes is consistent with the observed behaviour of the respective total cross-sections.

Riassunto

Si discutono le regolarità dello scattering ad alta energia che emergono dallo studio sperimentale degli scattering di pp, πp e Kp nel contesto di un modello con un pomerone schermato. In questo modello, la degenerazione di scambio delle traiettorie dei secondari è valida su un lungo intervallo di energia e le singolarità principali nel pianoj sono fattorizzabili. La singolarità del pomerone è essenzialmente un singolettoSU 3. La rottura della simmetriaSU 3 ad energie medio alte è attribuita ad una singolarità vicina, cioè al taglio dello schermo. Una conseguenza importante del modello presente è la predizione che la struttura osservata nella distribuzione angolare di pp con basso valore di |t| dovrebbe essere assente nel picco di diffrazione nello scattering di K+p. Infine, sulla base della struttura della singolarità nel modello si deduce che la dipendenza dall’energia delle pendenze delle curve di diffrazione è consistente con il comportamento osservato delle rispettive sezioni d’urto totali.

Реэюме

В рамках модели с зкранированным помероном обсуждаются регуляриэации дифракционного рассеяния при высоких знериях, исходя иэ зкспериментального исследования рр, πр и Кр рассеяния. В зтой модели обменное вырождение вторичных траекторий справедливо в щирокой области знергий и главные траектории qfакториэуемы вj-плоскости. Сингулярность померона представляет по сушеству синглетSU 3. НарущениеSU 3 при средних и высоких знергиях приписывается соседней сингулярности — зкранируюшему раэреэу. В предложенной модели предскаэывается, что наблюденная структура в рр угловом распределении при малых эначениях |t| должна отсутствовать в дифракционном пике в K+p рассеянии. В эаключение, на основе структуры сингулярности в зтой модели докаэывается, что знергетическая эависимость дифракционных наклонов согласуется с наблюденным поведением соответствуюших полных поперечных сечений.

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References

  1. W. Galbraith, E. W. Jenkins, T. F. Kycia, B. A. Leontic, R. H. Phillips andA. L. Read:Phys. Rev.,138, B 913 (1965);K. J. Foley, R. S. Jones, S. J. Lindenbaum, W. A. Love, S. Ozaki, E. D. Platner, C. A. Quarles andE. H. Willen:Phys. Rev. Lett.,19, 330, 857 (1967);S. P. Denisov, S. V. Donskov, Yu. P. Gorin, A. I. Petrukhin, Yu. D. Prokoshkin, D. A. Stoyanova, J. W. Allaby andG. Giacomelli:Phys. Lett.,36 B, 415 (1971);S. P. Denisov, S. V. Donskov, Yu. P. Gorin, A. I. Petrukhin, Yu. D. Prokashkin andD. A. Stoyanova:Nucl. Phys.,65 B, 1 (1973);A. S. Carroll, L.-H. Chang, T. F. Kycia, K. K. Li, R. O. Mazur, P. Mockett, D. C. Rahm, R. Rubinstein, W. F. Baker, D. P. Eartly, G. Giacomelli, P. F. M. Koehler, K. P. Pretzl, A. A. Wehmann, R. L. Cool andO. Fackler:Phys. Rev. Lett.,33, 932 (1974);V. Amaldi, R. Biancastelli, C. Bosio, G. Matthiae, J. V. Allaby, W. Bartel, C. Cocconi, A. N. Diddens, R. W. Dobinson andA. M. Wetherell:Phys. Lett.,44 B, 112 (1973);S. R. Amendolia, G. Bellettini, P. L. Braccini, C. Bradaschia, R. Castaldi, V. Cavasinni, C. Cerri, T. Del Prete, L. Foa, P. Giromini, P. Laurelli, A. Menzione, L. Ristori, G. Sanguinetti andM. Valdata:Phys. Lett.,44 B, 119 (1973).

  2. Yu. M. Antipov, G. Ascoli, R. Busnello, G. Damgaard, M. N. Kienzle-Focacci, W. Kienzle, R. Klanner, L. G. Landsberg, A. A. Lebedev, C. Lechanoine, P. Lecomte, M. Martin, V. Roinishvili, R. D. Sard, A. Weitsch andF. A. Yotch:Nucl. Phys.,57 B, 333 (1973);D. S. Ayers: Fermilab-Pub-75/48-EXP-ANL-HEP-PR-75-26/COO-3130PB-215.

    Article  ADS  Google Scholar 

  3. V. Bartenev, R. A. Carrigan Jr.,I.-Hung Chiang, R. L. Cool, K. Goulianos, D. Gross, A. Kuznetsov, E. Malamud, A. C. Melissinos, B. Morosov, V. Nikitin, S. L. Olsen, Y. Pilipenko, V. Popov, R. Yamada andL. Zohn:Phys. Rev. Lett.,31, 1367 (1973);U. Amaldi, R. Biancastelli, C. Bosio, G. Matthiae, J. V. Allaby, W. Bartel, M. M. Block, C. Cocconi, A. N. Diddens, R. W. Dobinson, J. Litt andA. M. Wetherell:Phys. Lett.,43 B, 231 (1973); see alsoW. Grein, R. Guigas andP. Kroll:Nucl. Phys.,89 B, 93 (1975);O. V. Dumbrais:Sov. Journ. Nucl. Phys.,13, 626 (1971).

    Article  ADS  Google Scholar 

  4. V. Barger:Proceedings of the XVII International Conference on High-Energy Physics (London, 1974), p. I-193; further references may be found in this article.

  5. R. E. Hendrick: Rockefeller University preprint COO-2232 B-58.

  6. S. Paranjape: University of Chicago preprint EFI 75/28, to be published inPhys. Rev. D, Comments and Addenda.

  7. R. K. Carnegie: SLAC-Pub-1609 (1975).

  8. R. Oehme:Phys. Rev. D,11, 1191 (1975) and references therein.

    Article  ADS  Google Scholar 

  9. C. Qigg andE. Rabinovici:Phys. Rev. D,13, 2525 (1976);R. Arnold:Phys. Rev. Lett.,14, 657 (1965).

    Article  ADS  Google Scholar 

  10. See alsoR. J. N. Phillips: Rutherford preprint RL-74-034;L. L. Jenkovszky andA. N. Wall: preprint ITP-74-166E (Kiev, 1975).

  11. H. Lipkin:Phys. Lett.,56 B, 76 (1975); see alsoJ. Pumplin andG. L. Kane:Phys. Rev. D,11, 1183 (1975).

    Article  ADS  Google Scholar 

  12. H. Cheng, R. Walker andT. T. Wu:Phys. Rev. D,11, 1827 (1975).

    Article  Google Scholar 

  13. R. Oehme andS. Paranjape:Phys. Rev. D,10, 2229 (1974).

    Article  ADS  Google Scholar 

  14. R. Oehme:Phys. Rev. D,9, 2695 (1974);D. Horn andF. Zachariasen:Hadron Physics at Very High Energies (Reading, Mass., 1973).

    Article  ADS  Google Scholar 

  15. R. Oehme: inStrong Interaction and High-Energy Physics, edited byR. G. Moorhouse (London, 1964), p. 129.

  16. R. Carlitz, M. B. Green andA. Zee:Phys. Rev. D,4, 3439 (1971).

    Article  ADS  Google Scholar 

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Authors and Affiliations

  1. Enrico Fermi Institute and Department of Physics, University of Chicago, 60637, Chicago, Ill.

    S. Paranjape

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  1. S. Paranjape
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Work supported in part by the NSF, contract No. PHYS74-08833 A01.

Submitted to the University of Chicago, the Department of Physics, in partial fulfilment for the requirements of the Ph. D. degree.

Present address: Tata Institute of Fundamental Research, Bombay 400 005, India.

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Paranjape, S. Role of shielding cuts in high-energy diffraction scattering. Nuov Cim A 42, 207–224 (1977). https://doi.org/10.1007/BF02724583

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