Relativistic quantum dynamics of a neutral particle in external electric fields: An approach on effects of spin

“…Therefore, the presence of the disclination modifies the result obtained by Johnson in [12], who studied the effect of rotation on the energy spectrum of free charges and its consequences to the Hall effect. Effectively, we obtain a rescaling of the angular momentum ℓby the defect parameter α as seen in equations (19)- (20). For a = 1 we recover the result of Johnson [12].…”

“…It should be noted that, for the case where the singular interaction is absent, only the regular solutions contribute for the bound state wave function ( º ℓ b 0), and the energy is given by equation (17) with the plus sign together with the condition  a | | ℓ 1. On the other hand, if a singular interaction is present, then the energy levels with the minus sign exist but the constraint < a | | ℓ 1 must be observed since this is the condition for the irregular wave function to be square integrable [20]. The energy spectrum above must be analyzed in terms of the values the parameter α can assume, since the condition  a | | ℓ 1( < a | | ℓ 1) for the regular (irregular) solution has to be fulfilled.…”

Inertial and topological effects on a 2D electron gas

“…Therefore, the presence of the disclination modifies the result obtained by Johnson in [12], who studied the effect of rotation on the energy spectrum of free charges and its consequences to the Hall effect. Effectively, we obtain a rescaling of the angular momentum ℓby the defect parameter α as seen in equations (19)- (20). For a = 1 we recover the result of Johnson [12].…”

“…It should be noted that, for the case where the singular interaction is absent, only the regular solutions contribute for the bound state wave function ( º ℓ b 0), and the energy is given by equation (17) with the plus sign together with the condition  a | | ℓ 1. On the other hand, if a singular interaction is present, then the energy levels with the minus sign exist but the constraint < a | | ℓ 1 must be observed since this is the condition for the irregular wave function to be square integrable [20]. The energy spectrum above must be analyzed in terms of the values the parameter α can assume, since the condition  a | | ℓ 1( < a | | ℓ 1) for the regular (irregular) solution has to be fulfilled.…”

Inertial and topological effects on a 2D electron gas

“…The resulting algebra of this contraction is a standard real Hopf algebra and depends on a dimension-full parameter κ instead of q. Since then, the algebraic structure of the κ -deformed Poincaré algebra has been investigated intensively and have become a theoretical field of increasing interest [2][3][4][5][6][7][8][9][10][11][12][13][14][15][16][17][18][19][20][21] . Through the field equations from the κ-Poincaré algebra (κ-Dirac equation [22][23][24]), we can study the physical implications of the quantum deformation parameter κ in relativistic and nonrelativistic quantum systems.…”

“…Through the field equations from the κ-Poincaré algebra (κ-Dirac equation [22][23][24]), we can study the physical implications of the quantum deformation parameter κ in relativistic and nonrelativistic quantum systems. In this context, we highlight the study of relativistic Landau levels [18], the Aharonov-Bohm effect taking into account spin effects [17], the Dirac oscillator [25,26] and the integer quantum Hall effect [27].…”

“…[32,33]). Some studies have been developed taking into account the spin and pseudospin symmetry limits to study relativistic dynamics of physical systems interacting with a class of potentials [34][35][36][37][38][39][40][41]. The present work is proposed to investigate the κdeformed Dirac equation derived in Refs.…”

Solution of the κ-Deformed Dirac Equation with Vector and Scalar Interactions in the Context of Spin and Pseudospin Symmetries

Exact solutions of the Dirac oscillator under the influence of the Aharonov–Casher effect in the cosmic string background