Akhter Md, Sultana S, Sen Gupta H, Petersen R (2001). Local optical model studies of pion-nucleus scattering. J. Phys. G. Nucl. Part. Phys. 27:755-771.
Crossref

Alam MM (1991). PhD Thesis, Department of Physics, Southern Illinois University, Illinois, USA.

Alam MM, Malik FB (2008). Private communications, unpublished.

Alam MM, Malik FB (1990). Nature of the Potential at Low Energy Using Inverse Scattering Method. Phys. Lett. B. 237:14-18.
Crossref

Alam MM, Malik FB (1991). An Inverse Scattering Method for Identical Particles. Nucl. Phys. A. 524:88-94.
Crossref

Albanese JP, Arvieux J, Bolger J, Boschitz E, Ingram CHQ, Jansen J, Zichy J (1980). Elastic Scattering of Positive Pions by 16O Between 80 and 340 MeV. Nucl. Phys. A 350:301-331.
Crossref

Bason E, Bos K, Bressani T, Chiavassa E, Costa S, Davies JD, Dellacasa G, Frame D, Gallio M, Jovanovich JV, Kernel G, Lourens W, Michaelis EG, Mirfakhrai N, Musso A, Panighini M,playfer SM, Rapetti M, Sever F, Stanovnik A, Tanner NW, Dantzig R, Eijk CWE, Doesburg V, Zephat AG (1981). Backward Elastic Scattering of Negative Pions from Oxygen in the (3,3) Resonance Region. CERN-EP-INT-81-04:1-13.

Begum L, Nahar W, Haque S, NasminRahman S, Rahman Md (2003). On Pion-Nucleus Scattering.The Abdussalam International Centre for Theoretical Physics, Trieste, Italy, 2003 (IC/2003/51); ibid (IC/2003/40). 

Binon F, Duteil P, Garron JP, Gorres J, Hugon L, Peigneux JP, Schmit C, Spighel M, Stroot JP (1970). Scattering of Negative Pions on Carbon. Nucl. Phys. B17:168-188.
Crossref

Blecher M, Gotow K, Anderson DK, Kerns R, Minehart R, Ziock K, Bercaw RW, Vincent JS, Johnson R (1974). Elastic Scattering of Negative Pions from and in the 3,3 Resonance Region. Phys. Rev. C 10:2247-2256.
Crossref

Clough AS, Turner GK, Allardyce BW, Batty CJ, Baugh DJ, McDonald WJ, Riddle RAJ, Watson LA, Cage ME, Pyle GJ, Squier GTA (1974). Pion-Nucleus Total Cross Sections from 88 to 860 MeV. Nucl. Phys. Lett. B76:15-28.
Crossref

Ebrahim AA, Khallaf SA (2005). Pion-12C Nucleus Optical Potential. Acta Phys. Pol. B 36:2071-2085.

Eisenberg J, Koltun D (1980). Theory of Meson Interaction with Nuclei. John Wiley and Sons, New York.

El-Azab Farid M, Ebrahim AA (2015). Analysis of π± - nucleus elastic and inelastic scattering using the single folding α–cluster Model. Phys. Scr. 90:015301-015313.
Crossref

Eriscson T, Weise W (1988). Pions and Nuclei. Clarendon Press, Oxford England.

FÓ“ldt G (1972). On the Pion-Nucleus Interaction in the (3, 3)-Resonance Region. Phys. Rev. C 5:400-412.

Fröhlich J, Schlaile HG, Streit L, Zingl H (1981). An Improvement of Coulomb Corrections in the Phase Shift Analysis of Elastic Scattering and Predictions of Cross Sections for Scattering at Low Energies. Z. Phys. A – Atoms Nuclei 302:89-94.

Germond JF, Wilkin C (1977).Why Are The Diffraction Minima in and Scattering from 12C so Different? Phys. Lett. 68B:229-233.
Crossref

Gmitro M, Kamalov S, Mach R (1987). Pion-Nucleus scattering at Low and Resonance Energies. Prog. Theor. Phys. Suppl. 91:60-72.
Crossref

Hirata M, Koch JH, Lenz F, Moniz EJ (1979). Isobar Hole Doorway States and pi O-16 Scattering. Ann. Phys. 120:205-248.
Crossref

Hong SW, Kim BT (1999). Phenomenological local potentials for π- + 12C scattering from 120 to 766 MeV. J. Phys. G. Nucl. Part. Phys. 25:1065-1078.
Crossref

Ingram Q, Boschitz E, Pflug L, Zichy J, Albanese JA, Arvieux J (1978). The Elastic Scattering of and by 16O and 40Ca Across the (3,3) Resonance. Phys. Lett. 76B:173-175.
Crossref

Johnson MB, Satchler GR (1996). Characteristics of Local Pion-Nucleus Potentials that are Equivalent to Kisslinger-Type Potentials. Ann. Phys. (New York) 248:134-169.
Crossref

Khallaf SA, Ebrahim AA (2000). Analysis of π± - nucleus elastic scattering using a local potential. Phys. Rev. C 62:024603-1-8.
Crossref

Khallaf SA, Ebrahim AA (2005). Phenomenological Local Potential Analysis of π+ Scattering. FIZIKA B 14:333-348.

Kisslinger LS (1955). Scattering of Mesons by Light Nuclei. Phys. Rev. 98:761-765.
Crossref

Kisslinger LS, Wang WL (1976). The Isobar-Doorway Theory for Pion-Nucleus Interactions. Ann. Phys. 99:374-434.
Crossref

Koch JH, Sternheim MM (1972). Models for Scattering at 270 MeV. Phys. Rev. C 6:1118-1120.
Crossref

Lee TSH, Redwine RP (2002). Pion-Nucleus Interactions. Ann. Rev. Nucl. Part. Sci. 52:23-63.
Crossref

Phatak SC, Tabakin F, Landau RH (1973). Pion-Oxygen Elastic Scattering in the 3-3 Resonance Region. Phys. Rev. C 7:1803-1809.
Crossref

Piffaretti J, Corfu R, Egger JP, Gretillat P, Lunke C, Schwarz E, Perrin C, Preedom BM (1977). Comparison of the and Elastic Scattering from 12C over the (3,3) Resonance Region. Phys. Lett. 71B:324-326.

Rahman Md, Sen Gupta HM (1991). Strong Absorption Model for Pion–Nucleus Scattering around the (3,3) Resonance. Phys. Rev. C 44:2484-2492.
Crossref

Safari R (2005). A Local Potential with Analytical Distorted Wave Approximation Model for Elastic Scattering of Pions from A Nucleus. Int. J. Pure Appl. Math. 23:283-289.

Satchler G (1992). Local potential model for pion-nucleus scattering and π+/π− excitation ratios. Nucl. Phys. A 540:533-576.
Crossref

Shalaby AS, Hassan MYM, and Al-Gogary MM (2007). Multiple Scattering Theory for Pion-Nucleus Elastic Scattering and the In- Medium Amplitude. Braz. J. Phys. 37:388-397.
Crossref

Shehadeh ZF (1995). PhD Thesis, Department of Physics, Southern Illinois University, Illinois, USA.

Shehadeh ZF (2008). Analysis of Low-Energy π+-40Ca Elastic Scattering Data. Proceedings of the 4th annual meeting of the Saudi Physical Society (SPS4), Edited by A. D. Alhaidari, H. A. Alhendi, and H. Bahlouli, Riyadh, 11-12 November, 2008 (KACST, Riyadh, 2009:24-30.

Shehadeh ZF (2009). Analysis of Pion-40Ca Elastic Scattering Data using the Klein-Gordon Equation. Int. J. Mod. Phys. E 18:1615-1627.
Crossref

Shehadeh ZF (2013a). Analyses of Elastically Scattered Charged Pions from 40Ca in the Intermediate-Energy Region. J. Assoc. Arab Univ. Basic Appl. Sci. 14:32-37.
Crossref

Shehadeh ZF (2013b). Analyses of elastically scattered charged pions from calcium isotopes and the 48Ca-54Fe isotone at 180 MeV. Turk. J. Phys. 37:190-197.
Crossref

Shehadeh ZF (2014a). Analyses of π±-12C Elastic Scattering and Reaction Cross Section Data Below, Atop and Above the Δ –Resonance. J. Mod. Phys. 5:341-352.
Crossref4

Shehadeh ZF (2014b).Analyses of π±-12C Elastic Scattering Data at 100 MeV using Inverse Scattering Theory and Klein-Gordon Equation. Int. Rev. Phys. 8:110-116.

Shehadeh ZF (2014c). Analyses of Low-Energy π--12C Elastic Scattering Data. J. Mod. Phys. 5:1652-1661.
Crossref

Shehadeh ZF (2015a).A Full Relativistic Treatment in Analyzing α-12C and α- 40,42,44,48 Ca Elastic Scattering Data at 1.37 GeV. Turk. J. Phys. 39:199-207.
Crossref

Shehadeh ZF (2015b). Analyses of Alpha-Alpha Elastic Scattering Data in the Energy Range 53.4-119.9 MeV. Can. J. Phys. 93:1-7.

Shehadeh ZF, Al-Shawaf RM (2015). Analyses of Elastic Scattering Data at : A Suggested Scaling Method. Mexican J. Phys. E Submitted.

Shehadeh ZF, Sabra MS, Malik FB (2003). Pion-40Ca Potential using Inverse Scattering Formalism and the Klein-Gordon Equation. Condensed Matter Theories 18:339-346.

Shehadeh ZF, Scott JS, Malik FB (2011). Analyses of π±-40Ca Elastic Scattering Data in the Delta Resonance Region using Inverse Scattering Theory and the Klein-Gordon Equation. Am. Institute Phys. J. 1370:185-191.

Stricker K (1979). PhD Thesis, Department of Physics, Michigan State University, Michigan, USA.

Stroot JP (1973). Experiments in Pion Nucleus Physics. Proceedings of LAMPF Summer School, LA-5443-C, edited by Gibbs WR, Gibson BF, July 23-26, 1973:1-13.

Walker GE (1973). Pion-Nucleus scattering assuming a separable microscopic pion-nucleon interaction. Lectures from the LAMPF Summer School on the Theory of Pion-Nucleus Scattering, LA-5443-C (July 23-26):72-86.

Zhang Y (1993). Pion-nucleus scattering and the Interacting Boson Model. Commun. Theor. Phys. 20:81-88.
Crossref