Solvable models of quantum beating
R. Carlone1, R. Figari2, C. Negulescu3, L. Tentarelli4
1Università "Federico II" di Napoli, Dipartimento di Matematica e Applicazioni "R. Caccioppoli",
MSA, via Cinthia, I-80126, Napoli, Italy 2Universita "Federico II" di Napoli, Dipartimento di Fisica e INFN Sezione di Napoli, MSA, via Cinthia, I-80126, Napoli, Italy 3Universite de Toulouse & CNRS, UPS, Institut de Mathematiques de Toulouse UMR 5219
F-31062 Toulouse, France
4Sapienza Universita di Roma, Dipartimento di Matematica, Piazzale Aldo Moro, 5, 00185, Roma, Italy
[email protected], [email protected], [email protected], [email protected]
PACS 03.65.-w, 02.30.Rz DOI 10.17586/2220-8054-2018-9-2-162-170
We review some results about the suppression of quantum beating in a one dimensional nonlinear double well potential. We implement a single particle double well potential model, making use of nonlinear point interactions. We show that there is complete suppression of the typical beating phenomenon characterizing the linear quantum case.
Keywords: nonlinear Schrodinger equation, weakly singular Volterra integral equations, quantum beating.
Received: 7 February 2018 Revised: 14 February 2018
1. Introduction
In the last decades, the quantum beating phenomenon has become a subject of great interest in different areas of quantum physics, ranging from quantum electrodynamics to particle physics, from solid state physics to molecular structure and dynamics.
Quantum beating was first experimentally observed in 1935 as a periodic inversion of the nitrogen atom with respect to the hydrogen atoms plane in the ammonia molecule. The phenomenon was then theoretically investigated examining the one dimensional dynamics of a quantum particle in a double well potential, the simplest example of a bistable potential. In Fig. 1, the two minima correspond to the average positions of the nitrogen atom in the two symmetric states.
Energy
H
H
N
H
/
H
H
Fig. 1. Schematical representation of Ammonia molecule.
The ammonia molecule is pyramidally shaped. Three hydrogen atoms form the base and the nitrogen atom is located in one of the two distinguishable states (enantiomers) on one side or the other with respect to the base (chirality). The experiments on liquid ammonia showed that microwave radiation could induce a periodic transition
from one state to the other (quantum beating). It was also observed that the periodic nitrogen inversion was absent whenever the molecule was part of a large organic structure or the pressure was too high.
Many authors used an effective nonlinear potential, superimposed on the double well, to model the interaction of the single molecule with the outside structure (see [1-4]).
The beating phenomenon for a particle in a double well potential is expected to be visible when the ground state and the first excited state have very close energies, forming an almost single, degenerate, energy level. A superposition of these two states will evolve, concentrating periodically inside one well or the other, with a frequency proportional to the energy difference (see section 2.2 below).
When a nonlinear effective potential is assumed to model the interaction with the environment the dynamics to be investigated is the nonlinear Schrodinger equation:
* dt=- f P2+v (*)+^r
dt 2 mdx2
where V(x) is a double well potential.
In order to comprehend the beating suppression induced by the environment one needs to prove that the nonlinear interaction destroys the periodic dynamics for all initial conditions, which in turn implies that the particle will be eventually confined to one of the wells (in which well the particle will finally collapse will depend on the specific chosen nonlinearity and/or on the initial conditions).
In a completely symmetric nonlinear double well, Sacchetti proved (see [5]) that for a = 2, the result holds true, in the semiclassical approximation (i.e., "ft ^ 0"). Related results were obtained in [6-9] in any dimension assuming a symmetry breaking nonlinear perturbation of the double well potential.
In [10], the beating phenomenon in the case of a linear and nonlinear "point well interactions" (for more, refer to [11]) is analyzed. The main advantage in using point interactions is that explicit solutions for the linear dynamics are available. Moreover, the analysis of the Schrodinger equation in the case of a nonlinear point interaction Hamiltonian can be reduced to the search of the solutions to a system of nonlinear Volterra integral equations for a complex function depending only on time. At least at the level of numerical computation this reduction turns out to be a remarkable simplification.
In this review, we recall first definition and properties of linear and nonlinear point interaction Hamiltonians. In the successive section, we consider a one dimensional Hamiltonian with two attractive point potentials. We examine its spectral properties and characterize the dependence of the energy difference between the ground state and the first exited state on the kinematical and dynamical parameters of the interaction. In this way, we will then be able to write down explicitly the beating solution for any range of parameters and successively to investigate the semiclassical limit.
We then investigate the Cauchy problem for the Schrodinger equation with two nonlinear point well potentials. As already mentioned, the description of the dynamics will be reduced to the analysis of a system of two Volterra integral equations. Based mainly on numerical analysis results, we will discuss the beating suppression.
2. The mathematical model - concentrated nonlinearities
First, we briefly recall the definition of point interaction Hamiltonians in L2(R) (see [11] for further details). For two point scatterers placed in Y = {y1,y2} of strength 7 = {71,72}, Vi, Yi € R, the formal Hamiltonian reads:
d2
Hy,Y * := " - dX2 * + Yisvi * + 72^2 * ", (1)
where the (reduced) Planck constant ft has been taken equal to one and the particle mass m equal to 1/2. We will also assume that the two points are placed symmetrically with respect to the origin and that |yi| = a.
The following result holds true (see [11]):
2 -1
D(H1,y) := {* € L2(R) | * = - £ (r*)^ 4>X(Vj)GX(-- y), € H2(R)} , (2)
(HX,Y + A) * = (-dX + A) f, (3)
are domain and action of a selfadjoint operator in L2 (R) which acts as the free Laplacian on functions supported outside the two points y = ±a. In (2) Gx(•) is the free Laplacian Green function:
e-VA|x|
Gx(x) :=
and the matrix is defined as:
(r^j := Y Sij + Gx(yi - yj),
where the positive real number A is chosen large enough to make the matrix invertible.
One can immediately verify that the derivative of Gx(x) has a jump in the origin, equal to —1. This in turn implies that every function ^ in the domain satisfies the boundary conditions:
dx (y+) — dx j = Yj ^) , j = i'2. (4)
The dynamics generated by is then characterized as the free dynamics outside the two scatterers, satisfying at any time the boundary conditions (4).
Our aim is to investigate the behavior of the solutions of the nonlinear evolution problem:
= H7(i)jY V(t, x) € R+ X R, ^(0, x) = ^o(x) € D(Hy(0)y), Vx € R, (5)
Yj(t):= 7|'^(t,Vj)|2", Y< 0, a > 0.
where the time dependence of 7 is nonlinearly determined by the values in ±a of the solution itself.
There is an alternative way to represent the solutions of the Cauchy problem (5). Let us consider the following ansatz, suggested by the Duhamel's formula applied to the evolution equation (5) using the formal definition (1) for the Hamiltonian,
2 4
V>(t,x) = (U(t)V>o)(x) — 17¿j U(t — s;x — yjMs,yj)|2ff$(s,yj) ds . (6)
j=i
0
where U(t, y) is the integral kernel of the unitary group e1tA, i.e.
U(t, y) := , (U№)(x)= U(t; x — y) £(y) dy, V£ € L2(R)
V4«nT J
From ansatz (6) one obtains for i = 1, 2:
2 t
^(t,yi) = (u (t)^o)(y») — «7 ¿J U (t — s; yi— yj )|^(s, yj )|2ct ^(s,yj) ds.
j=i
Explicitly
n , 7 f1 f *(S -a) Ms -a)|2a
*(t, -a) +w n J-vt-1-ds+
0
+ e1 (t-2) ds = (U(t) *o)(-a),
0
(7)
7 /i
*(t,a) + 2V n
*(s,a) l*(s,< Vt—s
■ ds+
7 M
*(s, -a) |*(s, -a)|2a „^l2
Vt —
e1 (t-s) ds = (U(t) *0)(a) .
The problem was extensively discussed in [12], where it was proved that, if *(t, ±a) are solutions of (7), then the function (6) is the unique solution of (5) (see [13-15] and [16,17] for d =2 and d = 3).
Remark 2.1. It is worth pointing out that the solution of (5) mentioned before is guaranteed to be global-in-time only if a < 1. On the other hand, whenever a > 1 there exist initial data for which blow-up phoenomena may arise.
Remark 2.2. Throughout, we use the notation q1(t) = *(t, -a), q2(t) = *(t, a) and refer to (7) as the "charge equations".
In the following subsection we examine the linear case analysing the necessary conditions to have quantum beating states.
2.1. Linear point interactions
Let us consider the linear case, corresponding to a = 0 and Yj < 0, for j = 1,2, independent of t in (5). From the definition (3) the resolvent of the operator HY,Y has integral kernel:
(H7,y + A)-1(x, x') = GA(x - x') - V (tA) 1 GA(x - Vi)GA(x' - yj). _ ... V —' ij
i,j=1
(8)
As it is clear from (8), HY,Y is a finite rank perturbation of the free Laplacian resolvent operator. This in turn implies that the essential spectrum of HY,Y is [0, to) and that -A is a negative eigenvalue if and only if the matrix rA is not invertible:
det r(7i ,72) =**
71 2 VA
GA(2a) — +
GA(2a)
1
or
1
— +
1
1
— +
1
1
72 ' 2 a/A
2
1
= -4\/Aa = 0
,71 2VV V72 2VaJ V^VAy All the relevant results concerning the point spectrum of HY,Y are collected in the following lemma.
72
Lemma 2.3 ( [10]). Let 71 < 72 and let us define the ratio a := —. Then, one has:
71
a): There are two real solutions A0 > A1 > 0 to equation (9) if and only if 7i < 0 for i = 1,2 and
1 1 2a |71| |72| .
b): For 7i = 7 < 0, i = 1, 2, satisfying (10) (1/7 < a) , one has
AA := Ao - A1 ^ 7 e In particular AA ^ 0 exponentially as |7|a ^ to.
2e-|Y|a
(9)
t
t
2
a
s
0
c): For Yi < 0, i = 1,2, satisfying (10) and a < 1, one has
AA := A0 - Ai > y2(1 - a2). In particular AA ^ to as |yi| ^ to.
d): For Yi < 0, i = 1, 2, satisfying (10) and a < 1, one has:
lim 2v/Wyi
| Y1
-1 ,
lim 2\J Ai
|Yl|
-1.
e): For Yi < 0, i = 1,2, satisfying (10), the eigenfunctions associated with the two negative eigenvalues are
(see [11])
^o(x) = c0GA° (x - y 1 ) + c 1 GXo (x - y2) : ^ 1 (x) = C2GAl (x - y 1 ) + csGAl (x - y2),
where the coefficients c0, c1 and c2, c3 are .solutions of:
(
1 1 YT + 2TA0
1
-2 VX0 C
1
V ^VAO
and
-2 yxo C
1
2^
Y2 + 2^
1
1
YT + 2 a/A!
1
e-2 vuC
1
-2 VU C
\ ^VAT
2%/AT
Y2 + 2 a/AT
1
(11) (12)
Solving explicitly the last equations at point e) of Lemma 2.3, we obtain:
The normalization condition finally gives:
co
c3
'(2y%/Yi) + 1 (2^Vy2) + 1 '
/(2vaT/y2) + 1 (2vaT/yI) + 1 .
2|Yi|A3/4
\/yiy2 (Yl+2vx0j + Yi (Yi + 4VaQ + 2VA0 a (yI + 2^A0))
21Y21 A'
3/4
^YiY2|y2+2vX1) - Y2 (y2 + 4VAT + 2V'ATa (Y2 + 2VAT))
(13)
(14)
A few remarks are worth noting:
Remark 2.4. In our units the condition characterizing the semi-classical limit is S := |y|« >> 1. In standard
— 2m y a
units the condition would be 5 := —^— >> 1 and the energy difference:
K2
AE - 2mY-e-5 . K2
Remark 2.5. Notice the extreme instability of the energy difference with respect to the ratio a when it is close to the value one. While in the symmetric case (a = 1) the energy difference is decreasing exponentially in the semiclassical limit the same quantity is going to infinity in the same limit for a < 1. This fact will appear to be the main reason in the quantum beating suppression in the asymmetric and in the nonlinear case.
Remark 2.6. In the semi-classical limit, the coefficient ratios (13) and (14) tend to 1 in the symmetric case (a = 1), whereas they tend to 0 for any a < 1. In turn, this means that, in the same limit, the eigenfunctions (11) and (12) tend to be equally distributed on the two wells if a = 1 whereas they are strongly confined in one of the well for any a < 1.
2
1
2.2. The beating phenomenon
Now, let us consider the linear case when the condition -1r + -¡-^ < 2a for the existence of two eigenvalues
iyii m1
is fulfilled. Following standard notation, we will use in this subsection subscripts "f, e" instead of 0,1 to mean "fundamental" and "first excited state" (respectively). The corresponding eigenfunctions are:
(x) = c0GAf (x + a) + ciGAf (x - a), ^e(x) = c2GAe (x + a) - c3GAe (x - a) . The superposition of the two eigenfunctions:
I.L
^6eai,0(x) := (^f (x) + ^e(x))
will evolve in time as follows:
1
(t,x) = ^ (elA/4¿f (x) + elAeVe(x))
P (t, x) = - (x)|2 + |^e(x)|2 +2 ¿f (x)^e(x) COS ((Af - Ae)t)] .
(15)
beai
with a probability density given by:
1 2
Let us consider first the symmetric case. The two eigenfunctions ¿f and are correspondingly symmetric and antisymmetric with respect to the origin and have similar absolute value everywhere (see Fig. 2).
Fig. 2. Plot of the functions ¿f (x) with a thicked blue line and ¿e(x) with a dashed line.
It is clear that ^Leai is initially supported around the point -a and is an oscillating function with period TB =
2n
—-—- concentrated periodically on the left and on the right well, justifying the definition of (15) as a beating
lAf - Ae|
The values assumed by the function ^Leoi(t,x) in the centers of the two wells evolve as follows:
qL(t) = -a) = — (elAfVf(-a) + elAeVe(-a)) ,
q2L(t) = V2,t(t, a) = — (elAfVf (a) + elAeVe(a)) .
and are plotted in Fig. 3.
The situation is remarkably different when a < 1. In this case, as we pointed out in Remark 2.6, the two eigenstates are strongly confined in different wells for large 71. In particular, their product is going to be zero almost everywhere. Any initial superposition of the two eigenstate:
^asy,o(x) := a^o(x) + £^i(x), a, £ € C, |a|2 + |£|2 = 1,
will evolve at time t into the state:
(t, x) := a e1 Ao 4 ¿0 (x) + £ e1 Al 4 ¿1 (x) .
Fig. 3. Plot of the time-evolution of the functions Re qf (t) as a dashed line, Im qf (t) as a dotted line and |qf |(t) as a thick line
but the time dependent term in the square modulus will be negligible and no beating phenomenon will take place.
One expects that the asymmetry due to the nonlinearity will produce a similar suppression on time scales depending on the initial condition and on the strength of the nonlinearity.
2.3. Nonlinear point interactions
A detailed analytical study of the nonlinear case a > 0 can be found in [12,18] where the authors prove general results about existence of solutions, either local or global in time, and prove existence of blow-up solutions for a > 1.
In the following, we analyze results about the evolution of a beating state obtained via numerical computation. A complete analytical analysis of equation (7) is still lacking. The problem is to quantify the amount of asymmetry necessary to suppress quantum beating induced by the nonlinearity and the time elapsed before that level is reached. Let us consider an initial state which would evolve in a quantum beating state in the linear case:
p0(x) := apf(x) + ppe(x), a, P G C |a|2 + |P|2 = 1
In the following we investigate the Cauchy problem (5) with initial conditions
p(0, x) = po(x)
using its integral form (7). From [12, Theorem 6], we know that, under the assumptions a < 1 and p0 G H 1 (R), the Cauchy problem has a unique solution which is global in time. Moreover in [12, Theorem 23], it is proved that if y < 0 and a > 1 then there exist initial data such that the solutions of the Cauchy problem blow-up in finite
Let us assume now that y < 0 and a < 1. We list the solutions to (7) obtained by numerical computation in [10]. In particular, we will compare the solution in the linear case with solutions to (7) with increasing powers of the non linearity. Our results show how the asymmetry generated by the nonlinear interactions produce the complete suppression of the beating phenomenon.
For the symmetric linear case we set a = 0 and consider the linear Volterra-system associated with the initial condition given by:
^6feai,o(x) := ap/ (x)+ PPe(x), a, P G R, (16)
which can be exactly solved:
q 1 (t) = a Pf (-a) elAf * + P pe( -a) el Ae *,
Vt G R+ .
q2(t) = aP/ (a) elAf * + PPe(a) elAe *,
Figure 4 presents on the left the time-evolution of the numerical solutions of the Volterra-system associated to the parameters indicated in the figure caption.
FIG. 4. The beating effect. Evolution in time of the numerical solutions |qi|2(t) resp. |q2|2(t) for a = 3, a = V0.01, 3 = V0.99, Y = -0.5
Let us consider the nonlinear case. We assume the same initial condition and the same parameters as in the symmetric linear case (16). Increasing the power of the nonlinearity (we consider a = 0.3, a = 0.7, a = 0.9) we observe that the time elapsed till the suppression of the beating effect is getting shorter and shorter. Here the time dependent point interaction strength is:
Y±(t) = Y |V(t, ±a)|2<T . In order to have at time t = 0 the same strength of the linear case y± (0) = -0.5, we assume
Y :=2Y±(0)/[|^c(a)|2T + |^q(-«)|2t] .
In Fig. 5, we plot the numerical solutions of the Volterra-system, i.e. |2(t) resp. |qn"m|2(t) (in blue resp.
red) as functions of time, and for the different nonlinearity exponents. As a reference, we plot also the exact solutions of the symmetric linear system, i.e. |qbeai,i|2(t) resp. |qbeai,2|2(t) (in cyan resp. magenta). Figures show clearly how the nonlinearity suppresses the beating-effect.
Fig. 5. The nonlinear time-evolution of the numerical solutions |qPm|2(t) resp. |qnum|2(t) (in blue/red full line) and corresponding linear beating solutions |qbeat 112 (t) resp. |qbeat 212(t) (in cyan/magenta dashed line), for a = 0.3 (left), a = 0.7 (center) and a = 0.9 (right)
3. Conclusion
In our numerical simulation, we showed that in a zero range nonlinear double well potential, the quantum beating mechanism is highly unstable under perturbations breaking the inversion symmetry of the problem.
The results shown in this review require further developments and extensions. In particular, it is necessary to examine analytically the solutions of the system of Volterra integral equations (7) to clarify the dependence on initial conditions of the time needed for the beating suppression. A generalization of the results to higher dimensions is in progress.
Acknowledgments
R. C. and L. T. acknowledge the support of the FIR 2013 project "Condensed Matter in Mathematical Physics", Ministry of University and Research of Italian Republic (code RBFR13WAET). C.N. would like to acknowledge support from the CNRS-PICS project "MANUS" (Modelling and Numerics of Spintronics and Graphenes, 2016 -
2018).
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