Acta Polytechnica


doi:10.14311/AP.2013.53.0427
Acta Polytechnica 53(5):427–432, 2013 © Czech Technical University in Prague, 2013

available online at http://ojs.cvut.cz/ojs/index.php/ap

COULOMB SCATTERING IN NON-COMMUTATIVE QUANTUM
MECHANICS

Veronika Gáliková, Peter Prešnajder∗

Faculty of Mathematics, Physics and Informatics, Comenius University of Bratislava, Mlynská dolina F2,
Bratislava, Slovakia

∗ corresponding author: presnajder@fmph.uniba.sk

Abstract. Recently we formulated the Coulomb problem in a rotationally invariant NC configuration
space specified by NC coordinates xi, i = 1, 2, 3, satisfying commutation relations [xi,xj] = 2iλεijkxk
(λ being our NC parameter). We found that the problem is exactly solvable: first we gave an exact
simple formula for the energies of the negative bound states Eλn < 0 (n being the principal quantum
number), and later we found the full solution of the NC Coulomb problem. In this paper we present
an exact calculation of the NC Coulomb scattering matrix Sλj (E) in the j-th partial wave. As the
calculations are exact, we can recognize remarkable non-perturbative aspects of the model: 1) energy
cut-off — the scattering is restricted to the energy interval 0 < E < Ecrit = 2/λ2; 2) the presence of two
sets of poles of the S-matrix in the complex energy plane — as expected, the poles at negative energy
EIλn = E

λ
n for the Coulomb attractive potential, and the poles at ultra-high energies EIIλn = Ecrit −E

λ
n

for the Coulomb repulsive potential. The poles at ultra-high energies disappear in the commutative
limit λ → 0.

Keywords: Coulomb scattering, non-commutativity, quantum mechanics.

Submitted: 12 March 2013. Accepted: 16 April 2013.

1. Introduction
The basic ideas of non-commutative geometry have
been developed in [1] and in a form of matrix geometry
in [2]. The analysis performed in [3] led to the conclu-
sion that quantum vacuum fluctuations and Einstein
gravity could create (micro)black holes which prevent
localization of space-time points. Mathematically this
requires non-commutative (NC) coordinates xµ in
space-time satisfying specific commutation relations.
e.g. Heisenberg-Moyal commutation relations

[xµ,xν] = iθµν,µ,ν = 0, 1, 2, 3, (1)

where θµν are given numerical constants that specify
the non-commutativity of the space-time in question.
Later in [4] it was shown that such field theories in
NC spaces can emerge as effective low energy limits
of string theories. These results supported a vivid de-
velopment of non-commutative QFT. However, such
models are very complicated and contain various un-
pleasant and unwanted features.
However, it may be interesting to reverse the ap-

proach. Not to use the NC geometry to improve the
foundations of QFT, but to test the effect of non-
commutativity of the space on well-defined problems
in quantum mechanics (QM), such as the harmonic
oscillator, the Aharonov-Bohm effect, the Coulomb
problem and the planar spherical well, see e.g. [5–7].
Recently, in [9, 10] we formulated the Coulomb

problem in a rotationally invariant NC configuration
space R3λ specified by NC coordinates xk, k = 1, 2, 3,

satisfying the commutation relations

[xi,xj] = 2iλεijkxk, (2)

where λ is a parameter of the non-commutativity
with the dimension of length. We found the model
exactly solvable. In [9] we gave an exact simple
formula for the NC negative bound state energies,
and in [10] we presented the full solution of the
NC Coulomb problem. In this paper we present
exact formulas for the NC Coulomb S-matrix in
the j-th partial wave. A similar construction of a
3D noncommutative space, as a sequence of fuzzy
spheres, was proposed in [11]. However, various
fuzzy spheres are related to each other differently
there (not leading to the flat 3D geometry at large
distances).

This paper is organized as follows. In Section 2 we
provide the formulation of the Coulomb problem in NC
space and we briefly describe the method of solution
suggested in [9] and [10]. In Section 3 we sketch the
determination of the Coulomb S-matrix in spherical
coordinates within standard QM (see [12]), and then
we generalize the calculations to the non-commutative
context. As the calculations are exact, we shall be
able to recognize remarkable non-perturbative aspects
of the NC Coulomb problem:

• the cut-off for the scattering energy E ∈ (0,Ecrit),
where Ecrit = 2/λ2;

• two sets of S-matrix poles: poles at energies E <
0 for attractive Coulomb potential and poles at

427

http://dx.doi.org/10.14311/AP.2013.53.0427
http://ojs.cvut.cz/ojs/index.php/ap


V. Gáliková, P. Prešnajder Acta Polytechnica

ultra-high energies E > Ecrit for repulsive Coulomb
potential that disappear in the commutative limit
λ → 0.

In Section 4 we provide a brief discussion and conclu-
sions.

2. Non-commutative quantum
mechanics

2.1. Non-commutative configuration
space

We realize the NC coordinates in R3λ, similarly as the
Jordan-Wigner realization of the fuzzy sphere in [8],
in terms of 2 pairs of boson annihilation and creation
operators aα, a†α, α = 1, 2, satisfying the following
commutation relations:

[aα,a
†
β] = δαβ, [aα,aβ] = [a

†
α,a
†
β] = 0. (3)

They act in an auxiliary Fock space F spanned by
normalized vectors

|n1,n2〉 =
(a†1)

n1 (a†2)
n2

√
n1!n2!

|0〉. (4)

Here |0〉≡ |0, 0〉 denotes the normalized vacuum state:
a1|0〉 = a2|0〉 = 0.

The noncommutative coordinates xj, j = 1, 2, 3, in
the space R3λ satisfying (2) are given as

xj = λa+σja ≡ λσ
j
αβa
†
αaβ,j = 1, 2, 3, (5)

where λ is the universal length parameter and σj are
Pauli matrices. The operator that approximates the
NC analog of the Euclidean distance from the origin
is

r = ρ + λ,ρ = λN,N = a†αaα. (6)

It can easily be shown that [xi,r] = 0, and r2 −x2j =
λ2. A strong argument supporting the exceptional
role of r will be given later.

2.2. Hilbert space Hλ of NC wave
functions

Let us consider a linear space spanned by normal
ordered polynomials containing the same number of
creation and annihilation operators:

Ψ = (a†1)
m1 (a†2)

m2 (a1)n1 (a2)n2,m1 + m2 = n1 + n2.
(7)

Hλ is our denotation for the Hilbert space of linear
combinations of functions (7) closed with respect to
the norm

‖Ψ‖2 = 4πλ3 Tr
[
(N +1)Ψ†Ψ

]
= 4πλ2 Tr[rΨ†Ψ]. (8)

The rotationally invariant weight w(r) = 4πλ2r is
determined by the requirement that a ball in R3λ with
radius r = λ(N + 1) should possess a standard volume
in the limit r →∞. It can be shown that the chosen
weight w(r) guarantees that the ball in question has
the volume Vr = 4π3 r

3 + o(λ).

Remark. The weighted trace Tr[w(r) . . .] with
w(r) = 4πλ2r goes to the usual volume integral∫
d3~x.. . at large distances. The 3D non-commutative

space proposed in [11] corresponds to the choice
w(r̂) = const and at large distances does not cor-
respond to the flat space R3.

2.3. Orbital momentum in Hλ
In Hλ we define orbital momentum operators, the
generators of rotations Lj, as follows:

LjΨ =
1
2

[a+σja, Ψ],j = 1, 2, 3. (9)

They are hermitian (self-adjoint) operators in Hλ and
obey the standard commutation relations

[Li,Lj]Ψ ≡ (LiLj −LjLi)Ψ = iεijkLkΨ. (10)

The standard eigenfunctions Ψjm, j = 0, 1, 2, . . . ,,
m = −j, . . . , +j, satisfying

L2i Ψjm = j(j + 1)Ψjm,L3Ψjm = mΨjm, (11)

are given by the formula

Ψjm =
∑
(jm)

(a†1)
m1 (a†2)

m2

m1! m2!
Rj(%)

an11 (−a2)
n2

n1! n2!
, (12)

where % = λa†αaα = λN. The summation goes over all
nonnegative integers satisfying m1 + m2 = n1 + n2 =
j, m1 − m2 − n1 + n2 = 2m. For any fixed Rj(%)
equation (12) defines a representation space for a
unitary irreducible representation with spin j.

2.4. The NC analog of Laplace
operator in Hλ

We postulate the NC analog of the usual Laplace
operator in the form:

∆λΨ = −
1
λr

[
a†α, [aα, Ψ]

]
=

1
λ2(N + 1)

[
a†α, [aα, Ψ]

]
. (13)

This choice is motivated by the following facts:
(1.) a double commutator is an analog of a second
order differential operator;

(2.) factor r−1 guarantees that the operator ∆λ is
hermitian (self-adjoint) in Hλ, and finally,

(3.) factors λ−1 or λ−2 respectively, guarantee the
correct physical dimension of ∆λ and its non-trivial
commutative limit.
Calculating the action of (13) on Ψjm given in

(12) we can check whether the postulate (13) is a
reasonable choice. First, we represent the operator
Rj(%) in (12) as a normal ordered form of an analytic
function Rj(%):

Rj(%) = :Rj(%): =
∑
k

c
j
k:%

k:

=
∑
k

c
j
kλ

k N!
(N −k)!

(14)

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vol. 53 no. 5/2013 Coulomb Scattering in Non-Commutative Quantum Mechanics

The last equality follows from the formula

:Nk:|n1,n2〉 =
n!

(n−k)!
|n1,n2〉,n = n1 + n2 (15)

(which can be proved by induction in k). Now we will
use the following commutation relations

[a†α, :N
k:] = −ka†α:N

k−1: ⇒ [a†α, :R:] = −λa
†
α:R

′:,
[aα, :Nk:] = k:Nk−1:aα ⇒ [aα, :R:] = λ:R′:aα, (16)

where R′ denotes the derivative of R: R′ =∑∞
k=1 kck%

k−1. Using (16), the following formula can
be derived:

[
a†α, [aα, Ψ]

]
=
∑
(jm)

(a†1)
m1 (a†2)

m2

m1!m2!

× :
[
−%R′′(%) − 2(j + 1)R′(%)

]
:
an11 (−a2)

n2

n1!n2!
. (17)

where R′′(%) is defined as the derivative of R′(%). In
the commutative limit λ → 0 the operator % formally
reduces to the usual radial r variable in R3, and we see
that ∆λ just reduces to the standard Laplace operator
in R3.

2.5. The potential term in Hλ
The operator V corresponding to a central potential
in QM is defined simply as the multiplication of the
NC wave function by V (r):

(V Ψ)(r) = V (r)Ψ = ΨV (r). (18)

In the commutative case the Coulomb potential
Φ(r) = −q

r
is the radial solution of the equation

∆Φ(r) = 0 (19)

vanishing at infinity. Due to our choice of the NC
Laplace operator ∆λ the NC analog of this equation
is

∆λΦ(r) = 0 ⇐⇒
[
a†α, [aα, Φ(N)]

]
= 0.

The last equation can be rewritten as a simple recur-
rent relation

(N + 2)Φ(N + 1) − (N + 1)Φ(N)
= (N + 1)Φ(N) −NΦ(N − 1) (20)

that can be easily solved. Its solution vanishing at
infinity is given as

Φ(N) = −
q′

N + 1
⇐⇒ Φ(r) = −

q

r
. (21)

We identify Φ(r) with the NC analog of the Coulomb
potential. We see that the 1/r dependence of the NC
Coulomb potential is inevitable.

3. The Coulomb problem in NC
QM

3.1. NC radial Schrödinger equation
Based on (13) and (21) we postulate the NC analog of
the Schrödinger equation with the Coulomb potential
in R3λ as

~2

2mλr
[
a†α, [aα, Ψ]

]
−
q

r
Ψ = EΨ

⇐⇒
1
λ

[
a†α,
[
aα, Ψ]

]
− 2αΨ = k2rΨ, (22)

where q is a square of electric charge q = ±e2 (q > 0 or
q < 0 corresponding to the Coulomb attraction or re-
pulsion respectively), α = mq/~2 and k2 = 2mE/~2.

Putting Ψ = Ψjm given in (12) into NC Schrödinger
equation (22) we come to the radial Schrödinger equa-
tion for Rj = :R:. Using (17) and the relation

rΨjm =
∑
(jm)

(a†1)
m1 (a†2)

m2

m1!m2!

× :[(% + λj + λ)Rj + λ%R′j]:
an11 (−a2)

n2

n1!n2!
, (23)

we obtain

:%R′′j + [k
2λ% + 2j + 2]R′j
+
[
k2% + k2λ(j + 1) + 2α

]
Rj: = 0. (24)

We claim (24) to be an NC analog of the usual radial
Schrödinger equation known from the standard QM.
There definitely is a resemblance, as in the limit λ → 0
the terms in (24) proportional to λ representing the
NC corrections disappear. Considering the same limit
we see that we also do not need to worry about the
colon marks denoting the normal ordering, since for
zero λ it makes no difference whatsoever whether we
care for the ordering or not.

Now we can solve the NC radial Schrödinger equa-
tion in two separate steps:

(1.) We associate the following ordinary differen-
tial equation to the mentioned operator radial
Schrödinger equation (24):

%R′′j + [k
2λ% + 2j + 2]R′j

+
[
k2% + k2λ(j + 1) + 2α

]
Rj = 0, (25)

with % being real variable, and we will solve this
one. But why do we expect this step to be of any
use to us, when we actually do have to care about
the ordering? The key information follows from
(16): the derivatives of R appearing in (17) are just
like carbon copies of the usual derivatives.

(2.) Now bearing this in mind, we put R = :R: , the
solution of (24), to be of the same form as R, the
solution of (25), except that % = λN and the normal

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V. Gáliková, P. Prešnajder Acta Polytechnica

powers :%n: have to be calculated. Fortunately there
is a simple formula relating the two, namely

:%n: = λn:Nn: = λn
N!

(N −n)!

:%−n: = λ−n:Nn: = λ−n
N!

(N −n)!
(26)

All we need is to rewrite :R: using those relations.
Then the comparison of QM and NCQM will be at
hand.

3.2. Coulomb scattering in QM
To begin with, we briefly sum up the QM results
before handling our NCQM case. The solution of
the radial Schrödinger equation for a particle in the
potential V (r) = −α/r with the angular momentum
j and energy E > 0 regular in r → 0 is given as

R
QM
j = e

ikrφ
(
j + 1 − i

α

k
, 2j + 2,−2ikr

)
,

k =
√

2E > 0, (27)

in terms of the confluent hypergeometric function (see
[12]):

φ(a,c,z) =
∞∑
m=0

(a)m
(c)m

zm

m!
. (28)

Here (a)m is the so-called Pochhammer symbol:
(a)m = a(a + 1) · · ·(a + m− 1), m = 0, 1, 2, . . . , and
(a)0 = 1. In (27) we have refrained from writing
down m/~2 explicitly. This will simplify the formulas
and will not do any harm, since the full form can be
restored anytime.
The solution (27) is real and for r →∞ it can be

written as the sum of two complex conjugated parts
corresponding to an in- and out-going spherical wave.
In the following formula a real factor common for both
parts is left out, having no influence on the S-matrix.

R
QM
j ∼

ij+1

Γ(j + 1 + iα
k

)
eikr+i

α
k

ln(2kr)

+
i−j−1

Γ(j + 1 − iα
k

)
e−ikr−i

α
k

ln(2kr). (29)

The S-matrix for the j-th partial wave is defined as
the ratio of the r-independent factors multiplying the
exponentials with the kinematical factor (−1)j+1 left
out:

S
QM
j (E) =

Γ(j + 1 − iα
k

)
Γ(j + 1 + iα

k
)
,

E =
1
2
k2 > 0. (30)

3.3. Coulomb scattering in NCQM
Now let us have a look on the Coulomb scattering in
NCQM. The solution of equation (25) regular at the

origin is again given in terms of confluent hypergeo-
metric function (see [10]):

Rj± = exp
[
(±π(E) −λE)%

]
×φ

(
j + 1 ±

α

π(E)
, 2j + 2,∓2π(E)%

)
, (31)

where

π(E) =
√

2E(
1
2
λ2E − 1). (32)

We point out that both Rj+ = Rj− due to the Kum-
mer identity valid for confluent hypergeometric func-
tion (see [13]).
Scattering solutions, containing in- and out-going

spherical waves, can be obtained only for energy prop-
erly restricted to the values

2E
(1

2
λ2E − 1

)
< 0 ⇐⇒ E ∈ (0, 2/λ2). (33)

Thus we recovered energy cut-off Ecrit = 2/λ2. For
E ∈ (0,Ecrit) we put

π(E) = ip, p =
√

2E
(
1 − 12λ

2E
)
> 0, (34)

and chose the solution (31) as REj = REj+; we
labeled the solution by the admissible value of en-
ergy E ∈ (0,Ecrit). The solution of the NC radial
Schrödinger equation (24) is REj = :REj:. Using (26)
the calculation is straightforward and we find for REj
the expression

REj =
(p + iλE
p− iλE

)N
×F

(
j + 1 − i

α

p
,−N, 2j + 2; 2iλp

p− iλE
p + iλE

)
(35)

in terms of the usual hypergeometric function

F(a,b; c; z) =
∞∑
m=0

(a)m(b)m
(c)m

zm

m!
. (36)

The radial dependence of Rj is present in the hermi-
tian operator N: r = % + λ, % = λN.
By analogy with (29) we will rewrite also the NC

solution as a sum of two hermitian conjugated terms
corresponding to the in- and out-going spherical wave.
First, we express REj as

REj = (1 −z)b/2F(a,b,c; z). (37)

According to Kummer identities (see [13]), F (a,b,c; z)
can be written as a linear combination of two other
solutions of the hypergeometric equation, namely

(−z)−aF(a,a + 1 − c,a + 1 − b; z−1)

and

(z)a−c(1 −z)c−a−bF
(
c−a, 1 −a,c + 1 −a−b; z−1

z

)
.

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vol. 53 no. 5/2013 Coulomb Scattering in Non-Commutative Quantum Mechanics

Again, leaving out the common hermitian factor which
is irrelevant regarding the S-matrix, we can write:

REj ∼
(−1)j+1eαπ/p

Γ(j + 1 + iα
p

)

(p + iλE
p− iλE

)N+j+1−iα
p

×
Γ(2j + 2)Γ(N + 1)

Γ(N + 2 + j − iα/p)
(2λp)−1−j+i

α
p

×F
(
A,B,C;−

i

2λp

(p + iλE
p− iλE

))
+

(−1)jeαπ/p

Γ(j + 1 − iα
p

)

(p− iλE
p + iλE

)N+j+1+iα
p

×
Γ(2j + 2)Γ(N + 1)

Γ(N + 2 + j + iα/p)
(2λp)−1−j−i

α
p

×F
(
A∗,B∗,C∗;

i

2λp

(p− iλE
p + iλE

))
, (38)

where

A = j + 1 − i
α

p
, B = −j − i

α

p
,

C = N + 2 + j − i
α

p
. (39)

In the limit r = λ(N + 1) →∞ this can be simplified
as (for details see ([10])):

REj ∼ (−1)j+1i−j−1e−απ/2p

×
Γ(2j + 2)

Γ(j + 1 − iα/p)
e−i

α
p

ln(2pr)

(2pr)j+1

× exp
[
−(r/λ + j + iα/p) ln

p + iλE
p− iλE

]
+ (−1)j+1ij+1e−απ/2p

×
Γ(2j + 2)

Γ(j + 1 + iα/p)
ei
α
p

ln(2pr)

(2pr)j+1

× exp
[
−(r/λ + j − iα/p) ln

p− iλE
p + iλE

]
. (40)

The S-matrix is the ratio of the r-independent factors
in (40):

Sλj (E) =
Γ(j + 1 − iα

p
)

Γ(j + 1 + iα
p

)
,

E =
1
λ2

(
1 + i

√
λ2p2 − 1

)
. (41)

The function E = E(p), given above with a positive
square root in for p ∈ (1/λ, +∞), is a conformal map
inverse to (34), which maps the cut p right-half-plane
into the E upper-half-plane.
The physical-relevant values of the S-matrix are

obtained as Sλj (E + iε) in the limit ε → 0+. The
interval corresponding to the scattering E ∈ (0, 2/λ2)
is mapped onto the branch cut in the p-plane as follows:
The energy interval E ∈ (0, 1/λ2) maps on the upper
edge of the branch cut p ∈ (0, 1/λ), whereas E ∈
(1/λ2, 2/λ2) maps on the upper edge of the branch
cut p ∈ (0, 1/λ).

3.4. Coulomb bound states as poles of
the S-matrix

We will begin a with brief reminder of the QM case:
Supposing the potential is attractive (α > 0), the
S-matrix (30) has poles in the upper complex k-plane
for

kn = i
α

n
, n = j + 1,j + 2, . . . . (42)

It is obvious that the bound state energy levels corre-
spond to the poles of the S-matrix:

En = −
α2

2n2
, n = j + 1,j + 2, . . . . (43)

In NCQM there is an analogy, the poles of the S-matrix
occur in the case of attractive potential (α > 0) for
some special values of energy below 0. However, poles
can also be found in the case of repulsive potential
(α < 0) for particular values of energy above 2/λ2.
(1.) Poles of the S-matrix for attractive poten-

tial.

pλn = i
α

n
α > 0

⇐⇒ EIλn =
1
λ2

(
1 −

√
1 + (λα/n)2

)
< 0,

n = j + 1,j + 2, . . . . (44)

In the limit λ → 0 this coincides with the standard
self-energies (43). Let us denote

κn =
λα

n
, ΩIn =

κn −
√

1 + κ2n + 1
κn +

√
1 + κ2n − 1

. (45)

Then the solution (35) is

RInj = (Ω
I
n)
NF
(
−n,−N, 2j + 2;−2κn(ΩIn)

−1).
(46)

It is integrable since Ωn ∈ (0, 1) for positive κn and
under given conditions the hypergeometric function
is a polynomial.

(2.) Poles of the S-matrix for repulsive poten-
tial.

pλn = i
α

n
α < 0

⇐⇒ EIIλn =
1
λ2

(
1 +

√
1 + (λα/n)2

)
> 2/λ2,

n = j + 1,j + 2, . . . . (47)

Now (35) has the form

RIInj = (−Ω
II
n )
NF
(
−n,−N, 2j + 2; 2κn(ΩIIn )

−1),
(48)

where

ΩIIn = −
κn +

√
1 + κ2n + 1

κn −
√

1 + κ2n − 1
. (49)

The definition of κn is the same as in (45) (note that
it is negative this time). Since ΩIIn = ΩIn ∈ (0, 1)
the solution (35) is integrable because the hyperge-
ometric function terminates as in the previous case.
These states disappear from the Hilbert space in
the limit λ → 0.

431



V. Gáliková, P. Prešnajder Acta Polytechnica

4. Conclusions
In this paper we have investigated the Coulomb scat-
tering in NCQM in the framework of the model for-
mulated in [9] and [10]. As the model is exactly
solvable, we were able to find an exact formula for the
NC Coulomb scattering matrix Sλj (E) in j-th partial
wave. We found that it turns out to have remarkable
non-perturbative aspects:

(1.) Energy cut-off — the scattering is restricted to
the energy interval 0 < E < Ecrit = 2/λ2;

(2.) Sλj (E) has two sets of poles in the complex energy
plane: as expected, the poles at negative energy
EIλn < 0 for attractive Coulomb potential that re-
duce to the standard H-atom bound states energies
in the commutative limit λ → 0, and poles at ultra-
high energies EIIλn = Ecrit −E

λ
n > Ecrit for repulsive

Coulomb potential which disappear for λ → 0.

In [10] these results have been confirmed by a direct
solution of the corresponding NC radial Schrödinger
equation. The analytic properties of Sλj (E) in the
complex energy plane indicate that the aspects of
causality in NCQM, within investigated model, are
fully consistent with the standard rôle and interpreta-
tion of S-matrix poles.

In [14] we constructed the Laplace-Runge-Lenz vec-
tor Akλ(E), k = 1, 2, 3, within our NC Coulomb model.
We found that at fixed energy level E < 0 and
E > Ecrit the model shows dynamical SO(4) sym-
metry with two sets of bound states for E = EIλn
and E = EIIλn, whereas for the scattering regime
0 < E < Ecrit = 2/λ2 the dynamical symmetry is
SO(3, 1), exactly as in the standard Coulomb prob-
lem.
In conclusion we claim that the investigated

Coulomb NC QM model, although containing un-
expected non-perturbative features, is fully consistent
with the usual QM postulates and interpretation.

References
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Noncommutative Geometry (Academic Press, London,
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[5] M. Chaichian, A. Demichev, P. Prešnajder, M.M.
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(2002) 149; H. Falomir, J. Gamboa, M. Loewe and J. C.
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[6] M. Chaichian, M.M. Sheikh-Jabbari and A. Tureanu,
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[10] V. Gáliková, P. Prešnajder, Coulomb problem in NC
quantum Mechanics: Exact solution and
non-perturbative aspects, arXiv:1302.4623; J. Math.
Phys. 54 (2013) 052102.

[11] A. B. Hammou, M. Lagraa and M. M.
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[12] L. Schiff, Quantum Mechanics, New York 1955.
[13] H. Bateman, Higher Transcendental Functions, Vol.
1, (Mc Graw-Hill Book Company, 1953).

[14] V. Gáliková, S. Kováčik, P. Prešnajder,
Laplace-Runge-Lenz vector for Coulomb problem in NC
Quantum Mechanics, (2013) arXiv:1309.4614v1.

432

http://arxiv.org/abs/1302.4623
http://arxiv.org/abs/1309.4614v1

	Acta Polytechnica 53(5):427–432, 2013
	1 Introduction
	2 Non-commutative quantum mechanics
	2.1 Non-commutative configuration space
	2.2 Hilbert space H lambda of NC wave functions
	2.3 Orbital momentum in H lambda
	2.4 The NC analog of Laplace operator in H lambda
	2.5 The potential term in H lambda

	3 The Coulomb problem in NC QM
	3.1 NC radial Schrödinger equation
	3.2 Coulomb scattering in QM
	3.3 Coulomb scattering in NCQM
	3.4 Coulomb bound states as poles of the S-matrix

	4 Conclusions
	References