Inequivalent Quantization in the Field of a Ferromagnetic Wire

J. Phys. A: Math. Theor.

2009

Self Cite

We show that the strength of non-commutativity could play a role in determining the boundary condition of a physical problem. As a toy model, we consider the inverse-square problem in non-commutative space. The scale invariance of the system is explicitly broken by the scale of non-commutativity Θ. The effective problem in non-commutative space is analyzed. It is shown that despite the presence of a higher singular potential coming from the leading term of the expansion of the potential to first order in Θ, it can have a self-adjoint extension. The boundary conditions are obtained, which belong to a 1-parameter family and are related to the strength of non-commutativity.

mentioning

confidence: 99%

“…. The solution of (10) has to be matched with (16) to get the relation of the non-commutativity parameter with the self-adjoint extension parameter . We see that there is exactly one bound state with the non-commutativity, 2 , and eigenfunction, ψ NC , being of the form…”

mentioning

confidence: 99%

Non-commutativity as a measure of inequivalent quantization

J. Phys. A: Math. Theor.

2009

Self Cite

“…It is known that usually the inclusion of spacetime noncommutativity destroys the uniterity of a system but that can be restored by a different formulation of noncommutativity of Doplicher et at [46,47] The present letter is concerned with a scale invariant * Electronic address: pulakranjan.giri@saha.ac.in system in non-commutative space. In particular we consider a particle on a plane (2D) with an inverse square potential [48,49,50,51,52,53,54,55]. The importance of the inverse square potential in theoretical physics can be understood from the huge research works carried out so far, which in some stage can be described by an inverse square potential.…”

mentioning

confidence: 99%

“…The importance of the inverse square potential in theoretical physics can be understood from the huge research works carried out so far, which in some stage can be described by an inverse square potential. Its presence is investigated in detail in molecular physics [52], atomic physics [50,52], black hole physics and mathematical physics. It shows that inverse square potential possesses bound state solution due to the scaling anomaly caused by quantization.…”

mentioning

confidence: 99%

Localization at the energy threshold in non-commutative space

2008

Physics Letters A

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The ground state energy of a scale symmetric system usually does not possess any lower bound, thus making the system quantum mechanically unstable. Self-adjointness and renormalization techniques usually provide the system a scale and thus making the ground state bounded from below. We on the other hand use noncommutative quantum mechanics and exploit the noncommutative parameter Θ as a scale for a scale symmetric system. The resulting Hamiltonian for the system then allows an unusual bound state at the threshold of the energy, E = 0. Apart from the Hamiltonian b H we also compute the other two generators of the so(2, 1) algebra, the dilation b D and the conformal generator b K in the noncommutative space. The so(2, 1) algebra is not closed in the noncommutative space, but the limit Θ → 0 smoothly goes to the so(2, 1) algebra restoring the conformal symmetry. We also discuss the system for large noncommutative parameter. The study of physics in noncommutative spacetime [1,2] or only in noncommutative space [3,4,5] has become an independent field of research work for a long time. It started with the work of Snyder [6,7], where Electromagnetic theory is considered in noncommutative spacetime. It is a well known fact that the coordinates of a plane become noncommutative when the quantum mechanical system in a magnetic field (perpendicular to plane) background is confined in lowest Landau level. However non-commutativity was present in theoretical physics before the concept of noncommutativity in spacetime or in space coordinates was introduced. For example, the canonically conjugate operators like coordinate x i and its conjugate momenta p i are noncommutative x i , p i = i , which leads to the uncertainty principle ∆x i ∆p i ≥ /2 in quantum mechanics. On the other hand although the different momentum components do commute, it is known that the components of a generalized momenta in the background magnetic field,k . Noncommutativity and its effect is studied in diverse fields starting from Quantum Field Theory [8,9,10,11,12,13,14], String theory [15,16,17,18] to quantum mechanics [19,20,21,22,23,24,25,26,27,28,29,30,31,32,33,34,35,36,37,38,39,40,41,42]. In quantum mechanical context several models are studied in noncommutative space. The list includes harmonic oscillator [43], Hydrogen atom problem [44,45], Zeeman effect and Stark [44] effect. Even the effect of noncommutative space is studied for a general central potential and solutions are obtained in large noncommutative limit [3]. It is known that usually the inclusion of spacetime noncommutativity destroys the uniterity of a system but that can be restored by a different formulation of noncommutativity of Doplicher et at [46,47] The present letter is concerned with a scale invariant * Electronic address: pulakranjan.giri@saha.ac.in system in non-commutative space. In particular we consider a particle on a plane (2D) with an inverse square potential [48,49,50,51,52,53,54,55]. The importance of the inverse square potential in theoretical physics can be understo...

INVERSE SQUARE PROBLEM AND so(2, 1) SYMMETRY IN NONCOMMUTATIVE SPACE

2009

Int. J. Mod. Phys. A

We study the quantum mechanics of a system with inverse square potential in noncommutative space. Both the coordinates and momenta are considered to be noncommutative, which breaks the original so(2, 1) symmetry. The energy levels and eigenfunctions are obtained. The generators of the so(2, 1) algebra are also studied in noncommutative phase space and the commutators are calculated, which shows that the commutators obtained in noncommutative space is not closed. However the commutative limit Θ, [Formula: see text] for the commutators smoothly go to the standard so(2, 1) algebra.