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Effects Of Distortion On Trojan Horse Applications

Rosario Gianluca Pizzone INFN – Laboratori Nazionali del Sud Catania. Effects Of Distortion On Trojan Horse Applications. quasi free break-up. a. s. x. c. A. C. virtual reaction in nuclear field A + x  c + C. The Trojan Horse Method.

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Effects Of Distortion On Trojan Horse Applications

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  1. Rosario Gianluca Pizzone INFN – Laboratori Nazionali del Sud Catania Effects Of Distortion On Trojan Horse Applications

  2. quasi free break-up a s x c A C virtual reaction in nuclear field A + x  c + C The Trojan Horse Method • Indirect Methods can improve Nuclear Astrophysics results. Among them the Trojan Horse Method(THM). • It allows the study of reactions of astrophysical interest like x(A,C)c at energies as low as the astrophysical ones after selection of an appropriate a(A,Cs)c reaction, induced at energies greater than the Coulomb barrier in quasi free conditions. (C. Spitaleri’s talk) For QF processes the binary cross section, as a function of the three body one is: What is F(ps)? Measured 3-body cross section 2-body cross section

  3. Outlook Knowing that: • Spectator momentum distribution in TH nucleus is necessary for THM application • TH nuclei (table) show a strong cluster configuration • In recent years the impulse distribution of spectator inside TH nucleus has been extensively studied for 6Li as a function of the transferred momentum ( Pizzone et al. 2005); Goal of the present work: to evaluate the momentum distribution distortion as a function of the transferred momentum also for the other nuclei used as TH nuclei

  4. a 6Li a d 6Li a F(ps): the momentum distribution • It represents the momentum distribution of the cluster s inside the Trojan Horse nucleus es. 6Li or 2H; • A very well known case: 6Li=a+d • (Pizzone et al, PRC 058801 2005) Step 1 to evaluate the distortion effects is the study of the a-d momentum distribution for 6Li

  5. Momentum distribution If the reaction proceeds via a QF mechanism the process is a direct one and the impulse distribution of the spectator should be identical to the one it has inside TH nucleus Since : Then ifd/d~ constant (small relative energy interval)  QF mechanism is present and can be separated from other contributions.

  6. Momentum distribution Dots: experimental momentum distribution (n in deuteron case) Red: DWBA calculation Black line: PWIA If -30<ps<30 MeV/c they almost agree (typical ranges for THM application, according to Shapiro prescriptions) Hulthen function: Standard parameters a=0.2317 fm-1 b=1.202 fm-1 Only one variable in the fit, the normalization constant

  7. B Momentum distribution for 6Li Low transferred momentum higher transferred momentum By increasing the transferred momentum the momentum distribution widens up

  8. FWHM vs. transferred momentum variation: 6Li • Step 2 investigate how momentum distribution shape changes with transferred momentum (reaction 6Li(6Li,aa)4He); Correlation FWHM – transferred momentum f0=73 MeV/c; q0=324MeV/c  Data from Barbarino et al. PRC 1980 • 6Li(6Li,aa)4He at different beam energies (2.1 – 44 MeV) 6Li(3He,ap)4He at different beam energies (5-6 MeV)

  9. Is this behaviour independent from Trojan Horse Nucleus?? • Deuterium • Helium 3 • Beryllium 9 • Tritium

  10. With growing transferred momentum the distribution width get closer to its asymptotic D=p+n FWHM vs. transferred momentum variation: 2H

  11. Additional study: momentum distribution for n in deuteron Experimental points are compared with theoretical prediction (Lamia et al., PRC, 2012) D wave contributing up to 4%.

  12. Remarks • We see therefore that for decreasing transferred momenta qt distortions in the momentum distribution of n inside d shows up. • This works also for other possible TH nuclei used in several experiments (Pizzone et al 2009)

  13. 3He=p+d FWHM vs. transferred momentum variation: 3He

  14. 9Be=a+5He FWHM vs. transferred momentum variation: 9Be

  15. FWHM vs. transferred momentum variation: tritium t=d+n

  16. Correlation between k and q0 Parameter f0, q0 and k=(2 m Eb)1/2 for examined nuclei

  17. Conclusions In all cases when transferred momentum is much higher than k the asymptotic value of the momentum distribution width is reached. Otherwise a narrowing shows up.That is a clear signature that distortion effects show up as soon as one get far from an “ideal” quasi free situation. One can take into account these effects by adopting in THM applications the effective momentum distribution instead of the asymptotic one. qt>>k qt~k

  18. Remarks: Distortions in THM • Distortions accounted for in THM by inserting in the experimental momentum distribution width (in general different from the asymptotic one). Two possible effects: • Impact of altered width in TH nucleus momentum distributions • Impact of assuming only s-wave contributes to the d wave function (e.g. for deuteron)

  19. FWHM = 70 MeV/c FWHM = 60 MeV/c FWHM = 50 MeV/c 1 • The S(E) factor for the 6Li(d,a)4He reaction has been extracted for different values of the momentum distribution FWHM • (Pizzone et al. 2005). No remarkable change (within experimental errors) differences around 5%

  20. 2 • The variation of the extracted S(E) factor for taking into account the d wave instead of the s wave alone in the n-p intercluster motion in d turned out to be negligible within experimental errors: In both the examined cases the discrepancy is less than 0.5%

  21. Bibliography:

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