Uncertainty Relations for Some Central Potentials in N-Dimensional Space ()

Sami M. AL-Jaber^{*}

Department of Physics, An-Najah National University, Nablus, Palestine.

**DOI: **10.4236/am.2016.76047
PDF
HTML XML
2,684
Downloads
3,736
Views
Citations

Department of Physics, An-Najah National University, Nablus, Palestine.

We study the uncertainty relation for three quantum systems in the N-dimensional space by using the virial theorem (VT). It is shown that this relation depends on the energy spectrum of the system as well as on the space dimension N. It is pointed out that the form of lower bound of the inequality, which is governed by the ground state, depends on the system and on the space dimension N. A comparison between our result for the lower bound and recent results, based on information-theoretic approach, is pointed out. We examine and analyze these derived uncertainties for different angular momenta with a special attention made for the large N limit.

Keywords

Heisenberg Uncertainty Relation, Central Potentials in N-Dimensions, Confined Particle, Hydrogen Atom, Harmonic Oscillator

Share and Cite:

AL-Jaber, S. (2016) Uncertainty Relations for Some Central Potentials in N-Dimensional Space. *Applied Mathematics*, **7**, 508-517. doi: 10.4236/am.2016.76047.

Received 16 December 2016; accepted 21 March 2016; published 24 March 2016

1. Introduction

Generally, uncertainty relations form an important part in the foundations of quantum mechanics and play a crucial role in the development of quantum information and computation [1] [2] . These relations establish the existence of an irreducible lower bound for the uncertainty in the results of simultaneous measurements of non- commuting observables. In other words, the precision with which incompatible physical observables can be prepared is limited by an upper bound. In particular, the Heisenberg uncertainty principle (HUP) [3] represents one of the fundamental properties of a quantum system. It gives an irreducible lower bound on the uncertainty in the outcomes of simultaneous measurements of position and momentum. Originally, HUP came from a thought experiment about measurements of the position and momentum, but later Kennard [4] derived a mathematical formulation of HUP by considering inherent quantum fluctuations of position and momentum without any reference to measurement process and which was then generalized by Robertson [5] for arbitrary incompatible observables. Recently, Fujikawa [6] proposed a universally valid uncertainty relation which incorporated both the intrinsic quantum fluctuations and measurement effects. There has been a continual interest in utilizing HUP in different settings. For example, it has been used in the study of central potentials [7] - [11] and others consider its connection to geometry [12] [13] . Furthermore, it has been generalized to describe a minimal length as a minimal uncertainty in position measurement [14] - [18] through the modification of Heisenberg commutation relation into a generalized form. The existence of a minimal length has long been suggested in quantum gravity and string theory [19] - [24] , and has been proposed to describe, as an effective theory, non-point like particles like hadrons, quasi-particles or collective excitations [25] . In its original formulation, HUP is expressed in terms of variances of position and momentum of a particle. Such variances do not necessarily exist, and if they do, they describe the quantum probability distribution relative to a specific point of the probability domain. Therefore, various alternative formulations have been suggested by the use of information-theoretic uncertainty measures like the Shannon entropy [26] [27] , Renyi entropies [28] [29] , Tsallis entropies [30] , entropic moments [31] [32] and Fisher information [32] - [36] . During the past years, the generalization of three dimensional quantum problems to higher space dimensions receives a considerable development in theoretical and mathematical physics. For example, the central potentials, as hydrogen-like atoms [37] - [42] and harmonic oscillators [43] - [46] are being used as prototypes for other purposes in N-dimensional physics. Furthermore, the confined harmonic oscillator [45] and the confined hydrogen atom [47] have been discussed. The purpose of the present paper is to de-

rive and discuss the uncertainty product for three quantum systems in N-dimensional space: the harmonic oscillator, the hydrogen atom, and a confined particle in an impenetrable symmetrical spherical well.

The lower bound for this product is analyzed and compared with other previous results that have been obtained by other methods. Our method is based on the virial theorem applied to the harmonic oscillator and the hydrogen atom systems to obtain the uncertainty product, while for the spherical well, the zeros of spherical Bessel functions are used for finding numerical results for the uncertainty product. Over the last years, the virial theorem technique has been employed in the study of physical quantities [48] [49] . Interesting features for the lower bound are discussed with a special attention explored for the large space dimension limit for the spherical well system. The organization of the paper is as follows: In section 2, we outline theoretical background. Then, we evaluate the uncertainty product for the harmonic oscillator quantum system in Section 3, for the hydrogen atom in Section 4, and for the spherical well in Section 5. We present conclusions and discussion of our work in Section 6.

2. Theoretical Background

The quantum mechanical state of a particle in the N-dimensional space with a central potential is governed by Schrödinger equation (setting)

(1)

where is the Laplacian operator on and is given by [50]

(2)

with is a partial differential operator which depends on the angular coordinates

as

, (3)

and satisfies [50]

, (4)

where are the hyperspherical harmonics characterized by quantum numbers with the condition. The separation of variables yields the radial part of Schrödinger equation that satisfies

(5)

which, by letting, becomes

. (6)

The above equation is the analogue to the one-dimensional Schrödinger equation with the grand orbital angular momentum, L given by

(7)

It is straight forward to write Equation (6) as

, (8)

where the effective potential, is given by

. (9)

It is worth to note, as seen from Equation (7), the isomorphism between the space dimension N and the orbital angular momentum ℓ, which means that an orbital angular momentum in space dimension N is equivalent to an orbital angular momentum ℓ in a space dimension. It is interesting to realize, as seen from Equation (9), that a particle is subject to two additional forces besides the force due to the external potential: The centrifugal force coming from the angular momentum term ( first term in brackets of Equation (9)) and a quantum fictitious force associated with the quantum-centrifugal potential (second term in brackets of Equation (9)) which has a purely dimensional origin. This potential is attractive for and repulsive for.

3. Isotropic Harmonic Oscillator in N-Dimensions

The potential for a harmonic oscillator is given by

(10)

The virial theorem states that

, (11)

where T is the kinetic energy and the average is taken over an energy eigenstate of the system. The substitution of Equation (10) into Equation (11) gives

, (12)

where the energy eigenvalues, are given by [45] , with

. (13)

Using with, and with the help of Equations (12) and (13), we get

and thus the uncertainty product is

, (14)

which obviously increases with both the quantum number n and the space dimension N. It is observed that the above product does not depend on the strength of the potential. The lower bound corresponds for the ground state and therefore, one may write the inequality for the uncertainty product, namely

, (15)

which saturates (equality is achieved) for nodeless harmonic oscillator wave function (ground state). Our results in Equation’s (14) and (15) are the same as those obtained by means of the Fisher’s information entropies [32] [33] , by Stamp’s principle [51] and by Shannon’s entropy [26] . Our method is more straight forward and simpler. The lower bound in Equation (15) reduces to the three-dimensional one, namely 9/4. Furthermore, our result in Equation (14) shows that the lower bound of the uncertainty product (for the ground state) in N-dimension is the

same as the lower bound of the excited state in the three-dimensional space. In addition, the uncer-

tainty product for a state with angular momentum in N-dimension has the same value as that for a state with angular momentum ℓ in a space dimension.

4. The Hydrogen Atom in N Dimensions

In this case, the potential is the coulomb potential,

(16)

The application of the virial theorem gives and using yields and. Therefore,

.

The energy eigenvalues for the eigenstates of a hydrogen atom in N dimensions are given by [37]

, (17)

where a is Bohr radius. Therefore, is readily obtained,

. (18)

In order to find the average of the moments of position of different powers we use Kramer’s relation in N- dimensions [52]

(19)

The successive application of the above relation for and after some algebra we get

(20)

The above relation and Equation (18) yield the uncertainty product for position and momentum;

(21)

It is clear to notice that the uncertainty product increases as the quantum number n increases and decreases as the orbital angular momentum ℓ increases. One can easily verify that the uncertainty product increases as the space dimension increases.

The lower bound of the above uncertainty is achieved by setting and, which means for ground state, with the result

(21)

In what follows, we will consider the uncertainty product given in Equation (20) for some special cases:

1) For the three-dimensional case (), our result reduces to a previous reported result [48] , namely

. (22)

2) For any state n with ℓ has its maximum value, the uncertainty product takes the form

(23)

In this case, the uncertainty product has its minimum value since ℓ has its maximum value, which means the certainty has its highest value. This result is a natural consequence of the quantum centrifugal potential which tries to repel the particle away from the nucleus. In fact, it was pointed out by AL-Jaber [37] that the radial probability density has its maximum value when the orbital angular momentum has its maximum value. This implies that the particle is more localized at this value of angular momentum and therefore the certainty is higher or the uncertainty is lower.

3) For any state n with, the uncertainty product takes the form,

, (24)

which corresponds to the maximum value of the uncertainty product, since ℓ has its minimum value. One may expect this result in the light of what we mentioned in the previous case.

4) The large space dimension limit: For large N, Equation (21) gives us the result

, (25)

which is equal to the lower bound for the ground state of the harmonic oscillator in N-dimensions as we found in the previous section. This clearly shows that in the large N limit the lower bound for any state becomes saturated and equals to that of the ground state lower bound of the harmonic oscillator.

5) The uncertainty product difference between a state with and. This is achieved by subtracting Equation (23) from Equation (24) with the result

(26)

The above equation gives, for a given state n, the uncertainty product difference between minimum and maximum angular momenta for that state. This difference increases with both n, and N. This shows how much the particle becomes delocalized due to maximum orbital angular momentum.

6) Spherically symmetric infinite potential well

In this section, we consider a particle that is confined in an infinite impenetrable spherical well so that the potential is given by

(27)

The substitution of the above potential into Equation (6) and letting, gives

, (28)

whose solution is the spherical Bessel function of order L, (the second solution has been dropped out since it diverges at the origin) and thus, the radial wave function is

. (29)

where A_{L} is a normalization constant. The allowed energies can be obtained by requiring, and thus

, with being the zero of the spherical Bessel function of order. The

successive zeros of depend on the order L, which depends on both ℓ and N. Therefore, the energies depend on ℓ and N, so that

. (30)

The integer n is the principal quantum number, which is the number of the root of spherical Bessel function in order of increasing magnitude. Since, we get

(31)

On the other hand, the average value, is given by

(32)

Following Grypeos [48] , we get

, (33)

which, upon the substitution for L from Equation (7), becomes

. (34)

The uncertainty product is now readily obtained using Equations (31) and (34), namely

. (35)

Again, the uncertainty product increases with both ℓ and N. The lower bound limit corresponds to ground state, , and the first zero of spherical Bessel function of order. In this case, we have

. (36)

The above result shows that the uncertainty product increases with space dimension N, but is independent of the size of the well. It is instructive to calculate the above lower limit for different values of space dimension and compare its values with those for the harmonic oscillator and the hydrogen atom. This is shown in Table 1.

The numerical values for the lower bound for the three systems, presented in Table 1, show that the harmonic oscillator has the smallest values for all space dimension. We also note that the hydrogen atom has higher lower bound value than that of the spherical well for space dimension 3 and 4, but beyond that the spherical well has higher values than those for hydrogen atom.

Table 1. Lower bound for the uncertainty product for the spherical well, harmonic oscillator, and the hydrogen atom as function of space dimension N.

It is interesting to check the large N limit of the lower bound of these systems: For the hydrogen atom, the lower bound behaves as which coincides with that of the harmonic oscillator. For the spherical well, the limit of the first zero for high order of is. In our case, this limit is just and therefore, Equation (36) gives a limit of, which is again the lower bound of the harmonic oscillator. We conclude that, in large N limit, both the hydrogen atom and the spherical well have lower bound values that converge to the same value which is equal to the lower bound of the harmonic oscillator. Therefore, the lower bound of the uncertainty product for those systems saturate in the large space dimension limit.

5. Conclusion

In this paper, we have derived the uncertainty product for position and momentum for harmonic oscillator, hydrogen atom, and spherically symmetric infinite well in N-dimensional space. We have found that this product depends on the orbital angular momentum and space dimension but independent of the strength of the potential. Our derivation relies on the virial theorem and Kramer’s relation for the harmonic oscillator and the hydrogen atom. Our results for the lower bound of the uncertainty product for each of the three systems agree with reported results for the three dimensional case. An interesting feature of our results is that in the large space dimension limit, the lower bound of the product for the hydrogen atom and the spherical well converge to that for the harmonic oscillator, namely, which means that the product saturate (for the ground state) in the large N limit. We have examined some features of the uncertainty product: For the harmonic oscillator, we have found

that the lower limit of the product in N-dimensions has the same value as that for the excited state in

three dimensions. Furthermore, the product for a state with angular momentum in N-dimensions is the same as that for a state with angular momentum ℓ in dimensions. For the hydrogen atom, we have found that the lower bound of the uncertainty product has the value, which reduces to 3 in the three dimensional space. In addition, the lower bound decreases as ℓ increases, and reaches its lowest value when ℓ gets to its maximum value,. This is expected since the radial probability distribution function is maximum at the maximum value of angular momentum, and thus the particle is expected to be more localized. Furthermore, we have derived the difference between the lower bounds for a state with and another with. This difference gives how much the particle becomes localized as the angular momentum increases from its lowest value to its maximum one. For the spherical infinite well, the lower bound is calculated by finding the first zero of spherical Bessel function of order. Due to the increase of the values of the zeros with the increase of the order of spherical functions, the lower bound of the product increases with the space dimension, N. It is observed that the value of the first zero approaches in the large N limit, and therefore, the lower bound becomes saturated with a value. Numerical values of the lower bound for the three systems are calculated and presented in Table 1.

Conflicts of Interest

The authors declare no conflicts of interest.

[1] | Price, W.C. and Chissick, S.S. (1997) The Uncertainty Principle and Foundations of Quantum Mechanics. Wiley, New York. |

[2] | Neilson, M.A. and Chuang, I.L. (2000) Quantum Computation and Quantum Information. Cambridge University Press, Cambridge. |

[3] |
Heisenberg, W. (1927) über den anschaulichen Inhalt der quantentheoretischen Kinematik und Mechanik. Zeitschrift für Physik, 43, 172-198. http://dx.doi.org/10.1007/BF01397280 |

[4] |
Kennard, E.H. (1927) Zur Quantenmechanik einfacher Bewegungstypen. Zeitschrift für Physik, 44, 326-352. http://dx.doi.org/10.1007/BF01391200 |

[5] |
Robertson, H.P. (1929) The Uncertainty Principle. Physical Review, 34, 163. http://dx.doi.org/10.1103/PhysRev.34.163 |

[6] |
Kujikawa, K. (2012) Universally valid Heisenberg Uncertainty Relation. Physical Review A, 85, Article ID: 062117. http://dx.doi.org/10.1103/PhysRevA.85.062117 |

[7] |
Kuo, C.D. (2005) The Uncertainties in Radial Position and Radial Momentum of an Electron in the Non-Relativistic Hydrogen-Like Atom. Annals of Physics, 316, 431-439. http://dx.doi.org/10.1016/j.aop.2004.09.005 |

[8] |
Chen, C.-Y., You, Y., Lu, F.-L. and Dong, S.-H. (2013) The Position-Momentum Uncertainty Relations for a Pöschl-Teller Type Potential and Its Squeezed Phenomena. Physics Letters A, 377, 1070-1075. http://dx.doi.org/10.1016/j.physleta.2013.02.043 |

[9] | Rudnicki, L. (2012) Heisenberg Uncertainty Relations for Position and Momentum beyond Central Potentials. Physical Review A, 85, Article ID: 022112. |

[10] |
Bracher, C. (2011) Uncertainty Relations for Angular Momentum Eigenstates in Two and Three Spatial Dimensions. American Journal of Physics, 79, 313. http://dx.doi.org/10.1119/1.3534840 |

[11] |
Patil, S.H. and Sen, K.D. (2007) Uncertainty Relations for Modified Isotropic Harmonic Oscillator and Coulomb Potentials. Physics Letters A, 362, 109-114. http://dx.doi.org/10.1016/j.physleta.2006.11.045 |

[12] |
Kryukov, A. (2007) Geometric Derivation of Quantum Uncertainty. Physics Letters A, 370, 419-422. http://dx.doi.org/10.1016/j.physleta.2007.09.038 |

[13] |
Anastopoulos, C. and Savvidou, N. (2003) The Role of Phase Space Geometry in Heisenberg’s Uncertainty Relation. Annals of Physics, 308, 329-353. http://dx.doi.org/10.1016/S0003-4916(03)00145-3 |

[14] |
Akhoury, R. and Yao, V.P. (2003) Minimal Length Uncertainty Relation and the Hydrogen Spectrum. Physics Letters B, 572, 37-42. http://dx.doi.org/10.1016/j.physletb.2003.07.084 |

[15] |
Pedram, P. (2012) A Higher Order GUP with Minimal Length Uncertainty and Maximal Momentum II: Applications. Physics Letters B, 718, 638-645. http://dx.doi.org/10.1016/j.physletb.2012.10.059 |

[16] |
Pedram, P. (2012) Nonperturbative Effects of the Minimal Length Uncertainty on the Relativistic Quantum Mechanics. Physics Letters B, 710, 478-485. http://dx.doi.org/10.1016/j.physletb.2012.03.015 |

[17] |
Sprenger, M., Nicolini, P. and Bleicher, M. (2012) Physics on the Smallest Scales: An Introduction to Minimal Length Phenomenology. European Journal of Physics, 33, 853. http://dx.doi.org/10.1088/0143-0807/33/4/853 |

[18] |
Hassanabadi, H., Hooshnand, P. and Zarrinkamar, S. (2015) The Generalized Uncertainty Principle and Harmonic Interaction in Three Spatial Dimensions. Few-Body Systems, 56, 19-27. http://dx.doi.org/10.1007/s00601-014-0910-7 |

[19] |
Maggiore, M. (1994) Quantum Groups, Gravity, and the Generalized Uncertainty Principle. Physics Review D, 49, 5182. http://dx.doi.org/10.1103/PhysRevD.49.5182 |

[20] |
Maggiore, M. (1993) A Generalized Uncertainty Principle in Quantum Gravity. Physics Letters B, 304, 65-69. http://dx.doi.org/10.1016/0370-2693(93)91401-8 |

[21] |
Garay, L.J. (1995) Quantum Gravity and Minimum Length. International Journal of Modern Physics A, 10, 145-165. http://dx.doi.org/10.1142/S0217751X95000085 |

[22] |
Majumder, B. (2011) Quantum Black Hole and the Modified Uncertainty Principle. Physics Letters B, 701, 384-387. http://dx.doi.org/10.1016/j.physletb.2011.05.076 |

[23] |
Amati, D., Gialfaloni, M. and Veneziano, G. (1989) Can Spacetime Be Probed Below the String Size? Physics Letters B, 216, 41-47. http://dx.doi.org/10.1016/0370-2693(89)91366-X |

[24] |
Hossenfelder, S. (2013) Minimal Length Scale Scenarios for Quantum Gravity. Living Reviews in Relativity, 16, 2. http://dx.doi.org/10.12942/lrr-2013-2 |

[25] |
Brau, F. (1999) Minimal Length Uncertainty Relation and the Hydrogen Atom. Journal of Physics A: Mathematical and General, 32, 7691-7696. http://dx.doi.org/10.1088/0305-4470/32/44/308 |

[26] |
Bialynicki-Birula, I. and Mycielski, J. (1975) Uncertainty Relations for Information Entropy in Wave Mechanics. Communications in Mathematical Physics, 44, 129-132. http://dx.doi.org/10.1007/BF01608825 |

[27] |
Rudnicki, L., Sanchez-Moreno, P. and Dehesa, J.S. (2012) The Shannon-Entropy-Based Uncertainty Relation for D-Dimensional Central Potentials. Journal of Physics A: Mathematical and Theoretical, 45, Article ID: 225303. http://dx.doi.org/10.1088/1751-8113/45/22/225303 |

[28] |
Zozor, S. and Vigant, C. (2007) On Classes of Non-Gaussian Asymptotic Minimizers in Entropic Uncertainty Principles. Physica A, 375, 499-517. http://dx.doi.org/10.1016/j.physa.2006.09.019 |

[29] |
Zozor, S., Portesi, M. and Vigant, C. (2008) Some Extensions of the Uncertainty Principle. Physica A, 387, 4800-4808. http://dx.doi.org/10.1016/j.physa.2008.04.010 |

[30] |
Rajagobal, A.K. (1995) The Sobolev Inequality and the Tsallis Entropic Uncertainty Relation. Physics Letters A, 205, 32-36. http://dx.doi.org/10.1016/0375-9601(95)00500-3 |

[31] |
Massen, H. and Uffink, J.B.M. (1988) Generalized Entropic Uncertainty Relations. Physical Review Letters, 60, 1103-1106. http://dx.doi.org/10.1103/PhysRevLett.60.1103 |

[32] |
Toranzo, I.V., Lopez-Rosa, S., Esquivel, R.O. and Dehesa, J.S. (2015) Heisenberg-Like and Fisher-Information-Based Uncertainty Relations for N-Electron d-Dimensional Systems. Physical Review A, 91, Article ID: 062122. http://dx.doi.org/10.1103/PhysRevA.91.062122 |

[33] |
Sánchez-Moreno, P., González, R. and Dehesa, J.S. (2006) Improvement of the Heisenberg and Fisher-Information-Based Uncertainty Relations for D-Dimensional Central Potentials. New Journal of Physics, 8, 330. http://dx.doi.org/10.1088/1367-2630/8/12/330 |

[34] |
Romero, E., Sánchez, P. and Dehesa, J.S. (2006) Uncertainty Relation for Fisher Information of D-Dimensional Single-Particle Systems with Central Potentials. Journal of Mathematical Physics, 47, Article ID: 103504. http://dx.doi.org/10.1063/1.2357998 |

[35] |
Hamilton, L.P. and Mosna, R.A. (2010) Fisher Information and Kinetic Energy Functionals: A Dequantization Approach. Journal of Computational and Applied Mathematics, 233, 1542-1547. http://dx.doi.org/10.1016/j.cam.2009.02.087 |

[36] |
Gibilisco, P., Imparato, D. and Isola, T. (2007) Uncertainty Principle and Quantum Fisher Information. II. Journal of Mathematical Physics, 48, Article ID: 072109. http://dx.doi.org/10.1063/1.2748210 |

[37] |
AL-Jaber, S.M. (1998) Hydrogen Atom in N Dimensions. International Journal of Theoretical Physics, 37, 1289-1298. http://dx.doi.org/10.1023/A:1026679921970 |

[38] | AL-Jaber, S.M. (2002) Ground-State Energy of the N-Dimensional Two-Electron Atoms. IL Nuovo Cimento B116, No.5 (2001), 593. |

[39] |
Kirchberg, A., Lange, J.D. and Wiph, A. (2003) Algebraic Solution of the Supersymmetric Hydrogen Atom in d Dimensions. Annals of Physics, 3003, 359-388. http://dx.doi.org/10.1016/S0003-4916(03)00003-4 |

[40] |
Nouri, S. (1999) Generalized Coherent States for the d-Dimensional Coulomb Problem. Physical Review A, 60, 1702-1705. http://dx.doi.org/10.1103/PhysRevA.60.1702 |

[41] |
AL-Jaber, S.M. and Lombard, R.J. (2005) Connection between the Spectrum and the Moments of the Ground-State Density in N-Dimensional Space. Journal of Physics A: Mathematical and General, 38, 4637-4644. http://dx.doi.org/10.1088/0305-4470/38/21/009 |

[42] | AL-Jaber, S.M. (2013) Solution of the Radial N-Dimensional Schrödinger Equation Using Homotopy Perturbation Method. Romanian Journal of Physics, 58, 247-259. |

[43] |
Demirlap, E. (2005) Bound States of n-Dimensional Harmonic Oscillator Decorated with Dirac Delta Functions. Journal of Physics A: Mathematical and General, 38, 4783-4794. http://dx.doi.org/10.1088/0305-4470/38/22/003 |

[44] |
Ghosh, S. and Majhi, B.R. (2008) Crypto-Harmonic Oscillator in Higher Dimensions: Classical and Quantum Aspects. Journal of Physics A: Mathematical and Theoretical, 41, Article ID: 065306. http://dx.doi.org/10.1088/1751-8113/41/6/065306 |

[45] | AL-Jaber, S.M. (2008) A Confined N-Dimensional Harmonic Oscillator. International Journal of Theoretical Physics, 47, 1853-1864. |

[46] |
Montgomery, H.E., Gampoy, G. and Aquino, N. (2010) The Confined N-Dimensional Harmonic Oscillator Revisited. Physica Scripta, 81, Article ID: 045010. http://dx.doi.org/10.1088/0031-8949/81/04/045010 |

[47] |
Shaqqor, M.A. and AL-Jaber, S.M. (2009) A Confined Hydrogen Atom in Higher Space Dimensions. International Journal of Theoretical Physics, 48, 2462-2472. http://dx.doi.org/10.1007/s10773-009-0041-y |

[48] |
Grypeos, M.E., Koutroulos, C.G., Oyewumi, K.J. and Petridou, T.A. (2004) The HVT Technique and the “Uncertainty” Relation for Central Potentials. Journal of Physics A: Mathematical and General, 37, 7895-7908. http://dx.doi.org/10.1088/0305-4470/37/32/005 |

[49] |
Grypeos, M.E., Koutroulos, C.G., Oyewumi, K.J. and Petridou, T.A. (2002) The HVT Technique and the Treatment of Two Basic Inequalities. Journal of Physics A: Mathematical and General, 35, 2223-2228. http://dx.doi.org/10.1088/0305-4470/35/9/312 |

[50] | Avery, J. (2000) Hyperspherical Harmonics and Generalized Sturmians. Kluwer, Dordrecht. |

[51] |
Romera, E. (2002) Stam’s Principle D-Dimensional Uncertainty-Like Relationships and Some Atomic Properties. Molecular Physics, 100, 3325-3329. http://dx.doi.org/10.1080/00268970210148778 |

[52] | Griffiths, D.J. (1995) Introduction to Quantum Mechanics. Prentice-Hall, New York. |

Journals Menu

Contact us

+1 323-425-8868 | |

customer@scirp.org | |

+86 18163351462(WhatsApp) | |

1655362766 | |

Paper Publishing WeChat |

Copyright © 2024 by authors and Scientific Research Publishing Inc.

This work and the related PDF file are licensed under a Creative Commons Attribution 4.0 International License.