Bound States of the Klein-Gordon for Exponential-Type Potentials in D-Dimensions

Advances in High Energy Physics

2013

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The two-dimensional (2D) relativistic bound states of a spinless particle placed in scalarS(r)and vectorV(r)Cornell potentials (withS(r)>V(r)) are obtained under the influence of external magnetic and Aharonov-Bohm (AB) flux fields using the wave function ansatz method. The relativistic energy eigenvalues and wave functions are found for any arbitrary state with principalnand magneticmquantum numbers. Further, we obtain the eigensolutions in any dimensional spaceDwithout external fields. We also find the relativistic and nonrelativistic bound states for Coulomb, harmonic oscillator, and Kratzer potentials.

Section: Discussionmentioning

confidence: 99%

Relativistic Bound States of Spinless Particle by the Cornell Potential Model in External Fields

Advances in High Energy Physics

2013

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“…Let us now consider the (3 + 1)-dimensional timeindependent KG equation describing a scalar particle with Lorentz scalar S(r) and Lorentz vector V (r) potentials which takes the form [53,54] …”

Section: Klein-gordon Equation For Equally Mixed Scalar-vector Yukawamentioning

confidence: 99%

“…In addition, we take the interaction potential as in (1) and decompose the total wave function ψ KG (r), with a given angular momentum l, as a product of a radial wave function R l (r) = g(r)/r, and the angular dependent spherical harmonic functions Y m l ( r ) [54] …”

Section: Klein-gordon Equation For Equally Mixed Scalar-vector Yukawamentioning

confidence: 99%

Klein–Gordon Solutions for a Yukawa-like Potential

Zeitschrift Für Naturforschung A

Hamzavi

2013

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The Klein-Gordon equation for a recently proposed Yukawa-type potential is solved with any orbital quantum number l. In the equally mixed scalar-vector potential fields S(r) = ±V (r), the approximate energy eigenvalues and their wave functions for a particle and anti-particle are obtained by means of the parametric Nikiforov-Uvarov method. The non-relativistic solutions are also investigated. It is found that the present analytical results are in exact agreement with the previous ones.

“…Also, β is an arbitrary constant demonstrating the ratio of scalar potential to vector potential [17]. When β = 1, it represents the case of spinless particle in equal mixture potentials, i.e., S(r) = V (r), which is being equivalent to the spin-1/2 fermion in the exact spin symmetric limit ∆ (r) = S(r) − V (r) = 0 (the potential difference is exactly zero).…”

Section: Introductionmentioning

confidence: 99%

Spinless Particles Subject to Unequal Scalar-Vector Nuclear Woods– Saxon Potentials in Arbitrary Dimensions

Hamzavi

Zeitschrift Für Naturforschung A

Rajabi

2013

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We present analytical bound state solutions of the spin-zero particles in the Klein-Gordon (KG) equation in presence of an unequal mixture of scalar and vector Woods-Saxon potentials within the framework of the approximation scheme to the centrifugal potential term for any arbitrary l-state. The approximate energy eigenvalues and unnormalized wave functions are obtained in closed forms using a parametric Nikiforov-Uvarov (NU) method. Our numerical energy eigenvalues demonstrate the existence of inter-dimensional degeneracy amongst energy states of the KG-Woods-Saxon problem. The dependence of the energy levels on the dimension D is numerically discussed for spatial dimensions D = 2 -6.