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Dissipative Dynamics and Uncertainty Measures of a Charged Oscillator in the Presence of the Aharonov-Bohm Effect

Abstract

We analyze the effects of dissipation in a charged oscillator in the presence of the Aharonov-Bohm effect by using time-dependent mass (m(t)) Hamiltonians. We consider two different models for the dissipative Hamiltonian and analyze the uncertainties (Δr and Δp) and the quantum mechanical expectation value of energy (⟨E⟩) in terms of time (t), damping parameters and flux parameter (v). For the Caldirola-Kanai model, we observe that the flux parameter v decreases the energy dissipation in a quantum dot for a certain range of t.

Keywords
Aharanov-Bohm effect; Caldirola-Kanai oscillators; Lane-Endem oscillators; uncertainty; mean energy; 2D parabolic quantum dot


1. Introduction

Since the 1920s, the interaction between charged particles and electromagnetic fields has attracted a great attention in the literature under the quantum mechanics point of view. Surprisingly, the particle motion can sometimes be influenced by electromagnetic fields in regions where both magnetic field B and electric field E are zero. As a matter of fact, the particle is affected by electromagnetic potentials, which may exist in regions where the fields do not exist. This effect was first pointed out in 1949 by Ehrenburg and Siday [11. W. Ehrenburg and R.E. Siday, Proc. Phys. Soc. B 62, 8 (1949).]. Using a semiclassical approach, they predicted a fringe shift due to magnetic vector potentials in a field-free region. Later, in 1959, Aharonov and Bohm [22. Y. Aharonov and D. Bohm, Phys. Rev. 115, 485 (1959).] discussed the role of the electromagnetic potentials in quantum mechanics. In the field-free multiply connected regions, the results of interference and scattering experiments depend on integrals of the potentials. This phenomenon has come to be called the Aharonov-Bohm (AB) effect.

Over the years, the AB effect has been experimentally verified [33. R.G. Chambers, Phys. Rev. Lett. 5, 3 (1960)., 44. A. Tonomura, N. Osakabe, T. Matsuda, T. Kawasaki, J. Endo, S. Yano and H.Yamada, Phys. Rev. Lett. 56, 792 (1986)., 55. N. Okasabe T. Matsuda, T. Kawasaki, J. Endo, A. Tonomura, S. Yano and H. Yamada, Phys. Rev. A 34, 815 (1986).] becoming a very interesting research area. The AB effect has been studied in several mesoscopic systems, such as metal rings [66. R.A. Webb, S. Washburn, C.P. Umbach, R.B. Laibowitz, Phys. Rev. Lett. 54, 2696 (1985).], carbon nanotubes [77. A. Bachtold, C. Strunk, J.P. Salvetat, J.M. Bonard, L. Forró, T.Nussbaumer and C. Schönenberger, Nature 397, 673 (1999)., 88. J. Cao, Q. Wang, M. Rolandi, H. Dai, Phys. Rev. Lett. 93, 216803 (2004).] and monolayer [99. S. Russo, J.B. Oostinga, D. Wehenkel, H.B. Heersche, SS. Sobhani, L.M.K. Vandersypen and A.F. Morpurgo, Phys. Rev. B 77, 085413 (2008)., 1010. M. Huefner, F. Molitor, A. Jacobse, A. Pioda, C. Stampfer, K. Ensslin and T.Ihn, Phys. Status Solidi B 246, 2756 (2009)., 1111. M. Huefner, F. Molitor, A. Jacobsen, A. Pioda, C. Stampfer, K. Ensslin and T. Ihn, New J. Phys. 12, 043054 (2010)., 1212. P. Recher, B. Trauzettel, A. Rycerz, Y.M. Blanter, C.W.J. Beenakker and A.F. Morpurgo, Phys. Rev. B 76, 235404 (2007).] and bilayer [1313. C.S. Park, Phys. Lett. A 381, 1831 (2017).] graphene. Ferkous and Bounames [1414. N. Ferkous and A. Bounames, Phys. Lett. A 325, 21 (2004).] obtained the energy spectrum and the eigenfunctions of a 2D Dirac oscillator in the presence of AB effect. They showed that the energies depend on the particle spin and the AB magnetic flux parameter. Bouguerra, Maamache and Bounames [1515. Y. Bouguerra, M. Maamache and A. Bounames, Int. J. Theor. Phys. 45, 1791 (2006).] using the invariant operator method [1616. H.R. Lewis Jr. and W.B. Riesenfeld, J. Math. Phys. 10, 1458 (1969).] obtained the exact wave-functions of a time-dependent 2D harmonic oscillator in the presence of the AB effect. They analyzed the case of a very thin solenoid (a flux tube of zero radius [1717. C.R. Hagen, Phys. Rev. Lett. 64, 53 (1990)., 1818. C.R. Hagen, Int J. Mod. Phys. A 6, 3119 (1991)., 1919. C.R. Hagen, Phys. Rev. D 64, 5935 (1993).]). The AB effect in presence of dissipation has also been investigated [2020. F. Guinea, Phys. Rev. B 65, 205317 (2002)., 2121. B. Horovitz and P. Le Doussal, Phys. Rev. B 74, 073104 (2006).]. Guinea [2020. F. Guinea, Phys. Rev. B 65, 205317 (2002).] obtained the amplitude of the AB oscillations of a particle on a ring threaded by a magnetic flux and coupled to different dissipative environments. One of these environments is the Caldeira-Leggett harmonic bath model [2222. A.O. Caldeira and A.J. Leggett, Phys. Rev. Lett. 46, 211 (1981).].

The Caldeira-Leggett model is a fundamental approach in which the system is coupled to a harmonic bath (a collection of harmonic oscillators) having many degrees of freedom. The energy flows from the system to the bath. However, there exists other approaches used to introduce dissipation in quantum mechanics [2323. H. Dekker, Phys. Rep. 81, 1 (1981)., 2424. N. Gisin, J. Phys. A: Math. Gen. 14, 2259 (1981)., 2525. P. Caldirola, Nuovo Cim. 18, 393 (1941)., 2626. E. Kanai, Prog. Theor. Phys. 3, 440 (1948)., 2727. R.W. Hasse, J. Math. Phys. 16, 2005 (1975)., 2828. D. Schuch, Phys. Rev. A 55, 935 (1997).]. Here we consider a phenomenological description which includes dissipation by means of explicitly time-dependent Hamiltonians [2525. P. Caldirola, Nuovo Cim. 18, 393 (1941)., 2626. E. Kanai, Prog. Theor. Phys. 3, 440 (1948)., 2727. R.W. Hasse, J. Math. Phys. 16, 2005 (1975)., 2828. D. Schuch, Phys. Rev. A 55, 935 (1997).]. This phenomenological approach is based on the so-called Caldirola-Kanai (CK) [2525. P. Caldirola, Nuovo Cim. 18, 393 (1941)., 2626. E. Kanai, Prog. Theor. Phys. 3, 440 (1948).] Hamiltonian, given by

(1) H ( t ) = e - γ ( t ) d t p 2 2 m 0 + e γ ( t ) d t V ( x ) ,

where x and p are position and momentum coordinates, respectively, and γ(t) is the damping coefficient. This model has already been used to study dissipative quantum tunneling [2929. S. Baskoutas, A. Janussis and R. Mignani, J. Phys. A: Math. Gen. 27, 2189 (1994)., 3030. M. Tokieda and K. Hagino, Phys. Rev. C 95, 054604 (2017).], time-dependent mesoscopic RLC circuits [3131. D. Xu, J. Phys. A: Math. Gen. 35, L455 (2002)., 3232. J.R. Choi, Phys. Scri. 73, 587 (2006)., 3333. I.A. Pedrosa, A.P. Pinheiro, Prog. Theor. Phys. 125, 1133 (2011)., 3434. I.A. Pedrosa, J.L. Melo and S. Salatiel, Eur. Phys. J. B 87, 269(2014)., 3535. V. Aguiar, I. Guedes and I.A. Pedrosa, Prog. Theor. Exp. Phys. 2015, 113A01 (2015).], damped effects on the entanglement of a two-level atom in a two-photon field [3636. A. Dehghani, B. Mojaveri and R. Jafarzadeh Bahrbeig, Int. J. Theor. Phys. 58, 865 (2019).], dissipative relativistic motion [3737. G. González, Int. J. Theor. Phys. 46, 417 (2007).], the matter black-body problem [3838. S. González-Hernández, M.A. Ramírez-Moreno and G. Ares de Parga, Phys. A 516, 472 (2019).], parabolic confined particles (dissipative quantum dots) [3939. S. Baskoutas, C. Politis, M. Rieth and W. Schommers, Phys. A 292, 238 (2001)., 4040. X.Y Pan, J.J. Zhu and Y.Q. Li, Phys. A 521, 293 (2019).] and the dynamics of the DNA breathing [4141. A. Sulaiman, F.P. Zen, H. Alatas and L.T. Handoko, Phys. D 241, 1640 (2012).]. The full correspondence between the system-reservoir approach and time-dependent Hamiltonians has been shown by Yun and Sun [4242. L.H. Yu and C.P. Sun, Phys. Rev. A 49, 592 (1994)., 4343. C.P. Sun and L.H. Yu, Phys. Rev. A 51, 1845 (1995).].

In this work we follow the procedure by Bouguerra, Maamache and Bounames [1515. Y. Bouguerra, M. Maamache and A. Bounames, Int. J. Theor. Phys. 45, 1791 (2006).] to study the effects of dissipation in a charged oscillator in the presence of the AB effect. This paper is organized as follows. In Section 2 2. Basic Definitions Consider the time-dependent Hamiltonian given by (2) H ⁢ ( t ) = ( p - e ⁢ A ) 2 2 ⁢ M ⁢ ( t ) + 1 2 ⁢ M ⁢ ( t ) ⁢ ω 2 ⁢ ( t ) ⁢ ( x 2 + y 2 ) , where A is the potential vector. Following Refs. [15, 17, 18, 19], for a flux tube of zero radius the corresponding potential A in the Coulomb gauge is given by (3) e ⁢ A = ν ⁢ ( y x 2 + y 2 , - x x 2 + y 2 , 0 ) , where ν is a finite nonzero flux parameter. The time-dependent Schrödinger equation for the Hamiltonian (2) with potential vector (3) reads (4) i ℏ ∂ ∂ ⁡ t ψ n ( r , t ) = [ p 2 2 ⁢ M ⁢ ( t ) + 1 2 M ( t ) ω 2 ( x 2 + y 2 ) + ( 2 ⁢ ν ⁢ L z + ν 2 ) 2 ⁢ M ⁢ ( t ) ⁢ ( x 2 + y 2 ) ] ψ n ( r , t ) , and Lz = xpx − ypx is the angular momentum in the z^ direction. According to Ref. [15] the solution of the time-dependent Schrödinger equation (4) reads (5) ψ n , m ( x , y , t ) = C n , m ρ e i m θ × e x p [ − i ( 2 n + | m + ν ℏ | + 1 ) ∫ 0 t 1 M ρ 2 d t ′ ] × e x p [ ( x 2 + y 2 ) ( i M ρ ˙ 2 ℏ ρ − 1 2 ℏ ρ 2 ) ] × ( x 2 + y 2 ) | m + ν ℏ | 2 × F 1 1 ( − n , | m + ν ℏ | + 1 , x 2 + y 2 ℏ ρ 2 ) where Cn,m=1Γ⁢(|m+νℏ|+1)⁢[Γ⁢(n+|m+νℏ|+1)n!⁢π⁢ℏ|m+νℏ|+1]1/2, θ=t⁢a⁢n-1⁢(yx), 1 F 1(a,b,c) denotes the confluent hypergeometric function of the first kind and ρ(t) satisfies the generalized Milne-Pinney (MP) [44, 45] equation (6) ρ ¨ + M . M ⁢ ρ . + ω 2 ⁢ ρ = 1 M 2 ⁢ ( t ) ⁢ ρ 3 . , we briefly explain the fundamental definitions needed for the calculations. In Section 3 3. Results and Discussion From Eq. (5) we write the following relations (7) ⟨ r 2 ⟩ n , m = ℏ ⁢ ρ 2 ⁢ ( 2 ⁢ n + | m + ν ℏ | + 1 ) , (8) ⟨ x ⟩ n , m = ⟨ y ⟩ n , m = 0 , (9) ⟨ p 2 ⟩ 0 , 0 = ℏ ⁢ ( | v | ℏ ⁢ M 2 ⁢ ρ . 2 + 1 + M 2 ⁢ ρ 2 ⁢ ρ . 2 ρ 2 ) , (10) ⟨ p x ⟩ 0 , 0 = ⟨ p y ⟩ 0 , 0 = 0 . Equations (7)–(10) are written in terms of ρ, a c-number quantity satisfying the generalized MP equation (see Eq. (6)). For a given M(t) and ω(t) one has to solve Eq. (6) and consider only real solutions of ρ so that I(t) is Hermitian. Observe that the Hamiltonian (2) describes the dynamics of dissipation in a 2D parabolic quantum dot in the presence of a Aharanov-Bohm effect if ω(t) = ω 0. Now let us consider the Caldirola-Kanai (CK) model, where M(t) = m 0 e γt and ω(t) = ω 0. In this case, the solution of the Milne-Pinney equation (6) is ρ=1m0⁢Ω⁢e-(γ⁢t2) (with Ω=ω02-γ24>0) [46]. In Figs. 1(a)–(b), we show plots of the uncertainties in position (Fig. 1(a)) and momentum (Fig. 1(b)) spaces of the system in the ground state. We show that both Δr and Δp increase with increasing ν. Figure 1(a) also shows that Δr tends to zero with increasing time as an effect of the dissipation (remember that classically the position of a damped oscillator tends to zero with increasing time, leading to a minimum uncertainty in the position). For v=0, we observed that the particle’s localization due to the CK dissipation is always lower than the uncertainty of a 2D parabolic quantum dot without dissipation and AB effect. On the other hand, for v=5 (v=10), the particle’s delocalization is greater than that of a 2D parabolic quantum dot without dissipation and AB effect in the range t < 1.9 (t < 2.5). Figure 1 Plots of (a) Δr and (b) Δp for v = 0 (solid line), v = 5 (large dashed line) and v=10 (short dashed line) for the ground state of the system by considering the CK dissipation. The dotted line corresponds to the uncertainties of a 2D parabolic quantum dot without dissipation and AB effect, where M(t) = m 0, ω(t) = ω 0 and v=0. In this figure we use ℏ = m 0 = ω 0 = γ = 1. From Eqs. (7)–(10) we see that the uncertainty product ΔrΔp obeys the Heisenberg Uncertainty Principle (ΔrΔp≥ℏ) and it does not depend on t. In Figs. 2(a)–(b) we plot ΔrΔp as function of γ and v, respectively. We observe that ΔrΔp increases nonlinearly (linearly) with the increasing of γ (v). Note also that ΔrΔp(γ) increases abruptly as γ approaches to γ→2ω 0 in the limit Ω→0. Figure 2 Plots of ΔrΔp as function of (a) γ and (b) v for the ground state of the system by considering the CK dissipation. In Figure 2(a) we keep v=1, while in Figure 2(b) γ = 1. The dotted line corresponds to the uncertainties of a 2D parabolic quantum dot without dissipation and AB effect, where M(t) = m 0, ω(t) = ω 0 and v=0. In both figures we use ℏ = m 0 = ω 0 = t = 1. Another class of damped system is the LE oscillator [47, 48, 49, 50] where M(t) = m0tα and ω(t) = ω 0. In this system the damping coefficient depends on time, γ⁢(t)=αt. For α = 2, the solution of the Milne-Pinney equation (6) is ρ=t-1m0⁢ω0 [48]. In Figs. 3(a)–(b) we show plots comparing the uncertainties in position (Fig. 3(a)) and momentum (Fig. 3(b)) spaces for a 2D quantum dot in the presence of the AB effect obtained from CK and LE dissipation in the ground state. For t < 2, we observe that the decrease of Δr due to the LE dissipation is steeper than that for the CK one. In this range, the LE damping coefficient is always greater than 1 and tends to + ∞ in the limit that t→0. We also observe that the particle is less localized due to LE dissipation for all values of t. Figure 3 Plots of (a) Δr and (b) Δp for CK (solid line) and LE (dashed line) oscillators for the ground state of the system. The dotted line corresponds to the uncertainties of a 2D parabolic quantum dot without dissipation and AB effect, where M(t) = m 0, ω(t) = ω 0 and v=0. In this figure we use v = γ = ℏ = m 0 = ω 0 = 1. Using the procedure described by Hasse [27], the time-dependent quantum mechanical expectation value of energy for the lowest-lying state is given by (11) ⟨ E ⟩ 0 , 0 = ℏ ⁢ m 0 2 ⁢ M ⁢ ( t ) ⁢ ( 1 + | v | ) × ( 1 M ⁢ ( t ) ⁢ ρ 2 ⁢ ( t ) + M ⁢ ( t ) ⁢ ρ . 2 ⁢ ( t ) + M ⁢ ( t ) ⁢ ω 0 2 ⁢ ρ 2 ⁢ ( t ) ) . In Fig. 4 we show plots of ⟨E⟩0,0 for different values of ν in a CK dissipative system. As expected, the energy decreases with increasing t. However, in the range t < 3.5 s we can minimize the dissipation in the 2D parabolic quantum dot by increasing ν. In Fig. 5 we compare the energies for both CK and LE systems. We observe that for t < 2 the LE dissipation is steeper than that of the CK one. This result is also due to the behavior of the LE damping coefficient in that range. Figure 4 Plots of ⟨E⟩0,0 for v = 0 (solid line), v = 5 (dashed line) and v = 10 (dotted line) for the ground state of the system by considering the CK dissipation. In this figure we use ℏ = m0 = ω0 = γ = 1. Figure 5 Plots of ⟨E⟩0,0 for CK (solid line) and LE (dashed line) oscillators for the ground state of the system. In this figure we use v = γ = ℏ = m0 = ω0 = 1. Summing up, we studied the effects of dissipation in a charged oscillator in the presence of the AB effect by using time-dependent mass (m(t)) Hamiltonians. The procedure used describes the dynamics of the dissipation in 2D parabolic quantum dot in the presence of AB effect. From the exact wavefunctions [15], we calculated the uncertainties (Δr and Δp) and the quantum mechanical expectation value of energy (⟨E⟩) for two kinds of dissipations and analyzed them with respect to time (t), damping parameters and flux parameter (v). For the CK system, we observed that Δr (Δp) decreases (increases) with increasing t and fixed v and γ, indicating that the particle becomes more and more localized. Since the oscillating particle radiates, the motion is damped and the particle oscillates between two closer and closer points reducing Δr. On the other hand, as v increases both Δr and Δp increase for a fixed t. The flux parameter depends on the transversal area A of the classical orbit. Therefore, the number of accessible points for the particle increases with increasing A leading to an increase of Δr. The increase of Δp results from the fact that when the orbit radius increase, the particle velocity must increase to keep the orbital period constant. By comparing the uncertainties Δr(t) for LE and CK dissipations in the range t < 2, we observed that the Δr decreasing due to the LE dissipation is sharper than that for the CK one. By analyzing the system under the CK dissipation, we also observed that the flux parameter v decreases the energy dissipation in a quantum dot for a certain range of t. This result can be useful to the improvement of quantum devices. A natural extension of this problem is the analysis of the quantum dynamics of a charged particle in an ion trap in the presence of dissipation. , we calculate the uncertainties and energy to both CK and Lane-Emden (LE) dissipative systems and summarize the results.

2. Basic Definitions

Consider the time-dependent Hamiltonian given by

(2) H ( t ) = ( p - e A ) 2 2 M ( t ) + 1 2 M ( t ) ω 2 ( t ) ( x 2 + y 2 ) ,

where A is the potential vector. Following Refs. [1515. Y. Bouguerra, M. Maamache and A. Bounames, Int. J. Theor. Phys. 45, 1791 (2006)., 1717. C.R. Hagen, Phys. Rev. Lett. 64, 53 (1990)., 1818. C.R. Hagen, Int J. Mod. Phys. A 6, 3119 (1991)., 1919. C.R. Hagen, Phys. Rev. D 64, 5935 (1993).], for a flux tube of zero radius the corresponding potential A in the Coulomb gauge is given by

(3) e A = ν ( y x 2 + y 2 , - x x 2 + y 2 , 0 ) ,

where ν is a finite nonzero flux parameter. The time-dependent Schrödinger equation for the Hamiltonian (2) with potential vector (3) reads

(4) i t ψ n ( r , t ) = [ p 2 2 M ( t ) + 1 2 M ( t ) ω 2 ( x 2 + y 2 ) + ( 2 ν L z + ν 2 ) 2 M ( t ) ( x 2 + y 2 ) ] ψ n ( r , t ) ,

and Lz = xpxypx is the angular momentum in the z^ direction.

According to Ref. [1515. Y. Bouguerra, M. Maamache and A. Bounames, Int. J. Theor. Phys. 45, 1791 (2006).] the solution of the time-dependent Schrödinger equation (4) reads

(5) ψ n , m ( x , y , t ) = C n , m ρ e i m θ × e x p [ i ( 2 n + | m + ν | + 1 ) 0 t 1 M ρ 2 d t ] × e x p [ ( x 2 + y 2 ) ( i M ρ ˙ 2 ρ 1 2 ρ 2 ) ] × ( x 2 + y 2 ) | m + ν | 2 × F 1 1 ( n , | m + ν | + 1 , x 2 + y 2 ρ 2 )

where Cn,m=1Γ(|m+ν|+1)[Γ(n+|m+ν|+1)n!π|m+ν|+1]1/2, θ=tan-1(yx), 1 F 1(a,b,c) denotes the confluent hypergeometric function of the first kind and ρ(t) satisfies the generalized Milne-Pinney (MP) [4444. W.E. Milne, J. Res. Natl. Bur. Stand. 43, 537 (1949)., 4545. E. Pinney, Proc. Am. Math. Soc. 1, 681 (1950).] equation

(6) ρ ¨ + M . M ρ . + ω 2 ρ = 1 M 2 ( t ) ρ 3 .

3. Results and Discussion

From Eq. (5) we write the following relations

(7) r 2 n , m = ρ 2 ( 2 n + | m + ν | + 1 ) ,
(8) x n , m = y n , m = 0 ,
(9) p 2 0 , 0 = ( | v | M 2 ρ . 2 + 1 + M 2 ρ 2 ρ . 2 ρ 2 ) ,
(10) p x 0 , 0 = p y 0 , 0 = 0 .

Equations (7)–(10) are written in terms of ρ, a c-number quantity satisfying the generalized MP equation (see Eq. (6)). For a given M(t) and ω(t) one has to solve Eq. (6) and consider only real solutions of ρ so that I(t) is Hermitian. Observe that the Hamiltonian (2) describes the dynamics of dissipation in a 2D parabolic quantum dot in the presence of a Aharanov-Bohm effect if ω(t) = ω 0.

Now let us consider the Caldirola-Kanai (CK) model, where M(t) = m 0 e γt and ω(t) = ω 0. In this case, the solution of the Milne-Pinney equation (6) is ρ=1m0Ωe-(γt2) (with Ω=ω02-γ24>0) [4646. I.A. Pedrosa, G.P. Serra and I. Guedes, Phys. Rev. A 56, 4300 (1997).]. In Figs. 1(a)–(b), we show plots of the uncertainties in position (Fig. 1(a)) and momentum (Fig. 1(b)) spaces of the system in the ground state. We show that both Δr and Δp increase with increasing ν. Figure 1(a) also shows that Δr tends to zero with increasing time as an effect of the dissipation (remember that classically the position of a damped oscillator tends to zero with increasing time, leading to a minimum uncertainty in the position). For v=0, we observed that the particle’s localization due to the CK dissipation is always lower than the uncertainty of a 2D parabolic quantum dot without dissipation and AB effect. On the other hand, for v=5 (v=10), the particle’s delocalization is greater than that of a 2D parabolic quantum dot without dissipation and AB effect in the range t < 1.9 (t < 2.5).

Figure 1
Plots of (a) Δr and (b) Δp for v = 0 (solid line), v = 5 (large dashed line) and v=10 (short dashed line) for the ground state of the system by considering the CK dissipation. The dotted line corresponds to the uncertainties of a 2D parabolic quantum dot without dissipation and AB effect, where M(t) = m 0, ω(t) = ω 0 and v=0. In this figure we use ℏ = m 0 = ω 0 = γ = 1.

From Eqs. (7)–(10) we see that the uncertainty product ΔrΔp obeys the Heisenberg Uncertainty Principle (ΔrΔp≥ℏ) and it does not depend on t. In Figs. 2(a)–(b) we plot ΔrΔp as function of γ and v, respectively. We observe that ΔrΔp increases nonlinearly (linearly) with the increasing of γ (v). Note also that ΔrΔp(γ) increases abruptly as γ approaches to γ→2ω 0 in the limit Ω→0.

Figure 2
Plots of ΔrΔp as function of (a) γ and (b) v for the ground state of the system by considering the CK dissipation. In Figure 2(a) we keep v=1, while in Figure 2(b) γ = 1. The dotted line corresponds to the uncertainties of a 2D parabolic quantum dot without dissipation and AB effect, where M(t) = m 0, ω(t) = ω 0 and v=0. In both figures we use ℏ = m 0 = ω 0 = t = 1.

Another class of damped system is the LE oscillator [4747. S.F. Özeren, J. Math. Phys. 50, 012902 (2009)., 4848. V.H.L. Bessa and I. Guedes, J. Math. Phys. 53, 122104 (2012)., 4949. V. Aguiar and I. Guedes, Phys. A 401, 159 (2014)., 5050. V. Aguiar and I. Guedes, Phys. Scr. 90, 045207 (2015).] where M(t) = m0tα and ω(t) = ω 0. In this system the damping coefficient depends on time, γ(t)=αt. For α = 2, the solution of the Milne-Pinney equation (6) is ρ=t-1m0ω0 [4848. V.H.L. Bessa and I. Guedes, J. Math. Phys. 53, 122104 (2012).]. In Figs. 3(a)–(b) we show plots comparing the uncertainties in position (Fig. 3(a)) and momentum (Fig. 3(b)) spaces for a 2D quantum dot in the presence of the AB effect obtained from CK and LE dissipation in the ground state. For t < 2, we observe that the decrease of Δr due to the LE dissipation is steeper than that for the CK one. In this range, the LE damping coefficient is always greater than 1 and tends to + ∞ in the limit that t→0. We also observe that the particle is less localized due to LE dissipation for all values of t.

Figure 3
Plots of (a) Δr and (b) Δp for CK (solid line) and LE (dashed line) oscillators for the ground state of the system. The dotted line corresponds to the uncertainties of a 2D parabolic quantum dot without dissipation and AB effect, where M(t) = m 0, ω(t) = ω 0 and v=0. In this figure we use v = γ = ℏ = m 0 = ω 0 = 1.

Using the procedure described by Hasse [2727. R.W. Hasse, J. Math. Phys. 16, 2005 (1975).], the time-dependent quantum mechanical expectation value of energy for the lowest-lying state is given by

(11) E 0 , 0 = m 0 2 M ( t ) ( 1 + | v | ) × ( 1 M ( t ) ρ 2 ( t ) + M ( t ) ρ . 2 ( t ) + M ( t ) ω 0 2 ρ 2 ( t ) ) .

In Fig. 4 we show plots of ⟨E0,0 for different values of ν in a CK dissipative system. As expected, the energy decreases with increasing t. However, in the range t < 3.5 s we can minimize the dissipation in the 2D parabolic quantum dot by increasing ν. In Fig. 5 we compare the energies for both CK and LE systems. We observe that for t < 2 the LE dissipation is steeper than that of the CK one. This result is also due to the behavior of the LE damping coefficient in that range.

Figure 4
Plots of ⟨E0,0 for v = 0 (solid line), v = 5 (dashed line) and v = 10 (dotted line) for the ground state of the system by considering the CK dissipation. In this figure we use ℏ = m0 = ω0 = γ = 1.
Figure 5
Plots of ⟨E0,0 for CK (solid line) and LE (dashed line) oscillators for the ground state of the system. In this figure we use v = γ = ℏ = m0 = ω0 = 1.

Summing up, we studied the effects of dissipation in a charged oscillator in the presence of the AB effect by using time-dependent mass (m(t)) Hamiltonians. The procedure used describes the dynamics of the dissipation in 2D parabolic quantum dot in the presence of AB effect. From the exact wavefunctions [1515. Y. Bouguerra, M. Maamache and A. Bounames, Int. J. Theor. Phys. 45, 1791 (2006).], we calculated the uncertainties (Δr and Δp) and the quantum mechanical expectation value of energy (⟨E⟩) for two kinds of dissipations and analyzed them with respect to time (t), damping parameters and flux parameter (v). For the CK system, we observed that Δrp) decreases (increases) with increasing t and fixed v and γ, indicating that the particle becomes more and more localized. Since the oscillating particle radiates, the motion is damped and the particle oscillates between two closer and closer points reducing Δr.

On the other hand, as v increases both Δr and Δp increase for a fixed t. The flux parameter depends on the transversal area A of the classical orbit. Therefore, the number of accessible points for the particle increases with increasing A leading to an increase of Δr. The increase of Δp results from the fact that when the orbit radius increase, the particle velocity must increase to keep the orbital period constant.

By comparing the uncertainties Δr(t) for LE and CK dissipations in the range t < 2, we observed that the Δr decreasing due to the LE dissipation is sharper than that for the CK one. By analyzing the system under the CK dissipation, we also observed that the flux parameter v decreases the energy dissipation in a quantum dot for a certain range of t. This result can be useful to the improvement of quantum devices. A natural extension of this problem is the analysis of the quantum dynamics of a charged particle in an ion trap in the presence of dissipation.

Acknowledgments

The authors are grateful to the National Counsel of Scientific and Technological Development (CNPq) and to the National Council for the Improvement of Higher Education (CAPES) of Brazil for financial support.

References

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Publication Dates

  • Publication in this collection
    08 Jan 2021
  • Date of issue
    2021

History

  • Received
    02 Nov 2020
  • Accepted
    01 Dec 2020
Sociedade Brasileira de Física Caixa Postal 66328, 05389-970 São Paulo SP - Brazil - São Paulo - SP - Brazil
E-mail: marcio@sbfisica.org.br